Method for determining three-dimensional structures of dynamic molecules

ABSTRACT

The present invention relates to a method for determining three-dimensional structures of molecules, particularly, but not exclusively, dynamic organic molecules of biological interest such as peptides, carbohydrates, proteins and drug molecules. A first aspect of the present invention provides a method for generating data representing an ensemble of three-dimensional structures of a molecule, the molecule comprising first and second atoms linked by at least one bond, said bond having an associated angle, and the angle varying to generate a plurality of three-dimensional structures of said molecule, the method comprising: receiving data representing said molecule, said data comprising data indicating variability of said angle; and generating an ensemble of structures such that the angle has an associated value selected based upon said variability. A second aspect of the present invention provides a computer implemented method for simulating the variability of the three-dimensional structure of a molecule.

The present invention relates to a method for determining three-dimensional structures of molecules, particularly, but not exclusively, dynamic organic molecules of biological interest such as peptides, carbohydrates, proteins and drug molecules.

Many important molecules have intrinsically flexible and dynamic structures, for example, peptides, carbohydrates, antibiotics, organic drug molecules and proteins. In many biochemical analyses a knowledge of the three-dimensional (3D) structure of such molecules in solution is desirable, in order to understand their physicochemical properties, the effect of chemical modifications or how they interact with other molecules, such as proteins.

Current approaches often solely use computational molecular modelling to understand 3D-structure of molecules, which has significant uncertainly because molecular potential energy surfaces are not well understood in solution and experimental data is rarely incorporated into models of the molecule component of a system under study. One of the significant challenges with using experimental data to define the 3D-structure of small molecules is that they are often relatively disordered in solution, meaning that dynamics has to be taken into account and has meant that the problem of determining their 3D-structure in solution has remained largely unsolved. A procedure that can accurately define the 3D-structure of small molecules would enable many processes that have so far been regarded as inaccurate, such as rational drug design and virtual screening.

An object of the present invention is to obviate or mitigate drawbacks associated with current methods for determining the 3D-structure of molecules.

A first aspect of the present invention provides a method for generating data representing an ensemble of three-dimensional structures of a molecule, the molecule comprising first and second atoms linked by at least one bond, said bond having an associated angle, and the angle varying to generate a plurality of three-dimensional structures of said molecule, the method comprising:

-   -   receiving data representing said molecule, said data comprising         data indicating variability of said angle; and     -   generating an ensemble of structures such that the angle has an         associated value selected based upon said variability.

This aspect of the present invention provides a computational method for generating an ensemble of 3D-structures of a molecule which can then be utilised in a number of further applications. For example, in one preferred embodiment the ensemble of structures can be analysed to provide one or more types of predicted experimental data which can then be compared to corresponding real experimental data. The comparison can be used to drive an optimisation procedure whereby the ensemble of structures is modified a number of times and the comparison of predicted to experimental data repeated for each ensemble until the optimum ensemble of structures is identified which provides the closest comparison of real to predicted experimental data.

An important feature of a preferred embodiment of the invention is that it facilitates optimisation of an ensemble of 3D-molecular structures against one or more types of real experimental data simultaneously, which can be particularly important when one type of experimental data alone would be insufficient to properly characterise a solution 3D-structure of a molecule. This is exemplified below in Examples 1, 2 and 3.

A second aspect of the present invention provides a computer implemented method for simulating the variability of the three-dimensional structure of a molecule, the molecule comprising first and second atoms linked by at least one bond, said bond having an associated angle, and the angle varying to generate a plurality of three-dimensional structures of said molecule, the method comprising:

-   -   receiving data representing said molecule, said data comprising         data indicating variability of said angle;     -   simulating the variability of the three-dimensional structure of         the molecule based upon said data indicating variability of said         angle; and     -   generating an ensemble of structures such that the angle has an         associated value selected based upon said simulating.

The present invention has applicability to a wide range of molecules, such as, but not limited to the following examples:

-   -   1) carbohydrate ligands and carbohydrate-mimetics (e.g.,         aminoglycoside antibiotics);     -   2) peptides and artificial peptide mimetics;     -   3) drug molecule molecular flexibilities;     -   4) flexible protein sidechains within an enzyme/receptor active         site or protein-protein interaction site;     -   5) flexible bases within nucleic acid molecules, (e.g, RNA         aptamers); and     -   6) proteins with several conformational states (e.g., integrins)         and intrinsically unfolded proteins.

Projects requiring structural information on flexible molecules will dramatically benefit from dynamic structures generated according to the present invention, particularly those involving ligand-protein interactions, such as rational drug design, which relies upon interaction-energy predictions. Such predictions based on prior art models are currently poor (only ˜10% of predicted molecules successfully bind to their receptor), because although enthalpic contributions can be estimated well, entropic contributions cannot. Using both the drug molecule's preferred structure (internal enthalpy) and dynamic motions (entropy) determined using the methodology according to the present invention will therefore result in significant improvements in hit identification and lead optimisation via rational drug design approaches [30]. Moreover, the methods of the present invention and the dynamic 3D-structures that are produced from them can be used to calculate the deviation of a free solution structure from its bound form which can then be used as an accurate scoring function to compare and select candidate molecules.

Example 4 below presents a series of results for different organic molecules which demonstrates the accuracy with which the methods of the present invention can predict the bioactive (i.e. ligand-bound) conformation of those molecules. Example 5 below describes how a comparison of the dynamic 3D structures of lisinopril and AngiotensinI generated using methods according to the present invention suggested a modification to the chemical structure of lisinopril that anticipated structural features of the next-generation ACE-inhibitor Benazeprilat. This result clearly demonstrates how the methods of the present invention can provide dynamic 3D structures that will greatly aid lead optimisation decisions by medicinal chemists.

A further application for 3D dynamic structures generated according to the methods of the present invention is in improved virtual screening results. The 3D dynamic structure of a natural ligand or drug can be used as a more accurate 3D conformational template or pharmacophore map for the query compound than theoretically-generated 3D conformations in virtual screening techniques that search for other molecules in a database that can have a similar shape to the query compound. Typically, to overcome uncertainty over the query compound's preferred shapes, virtual screening strategies use many conformational variants for each query. By employing the methodology of the present invention, these many potential derivatives can be replaced by a single or, at most, several key preferred conformations determined directly from experiment—reducing the computational complexity and time of a search by several orders of magnitude. Molecules identified from such a virtual screen may be new hits or backbone scaffold-hops for the development of a new drug.

Another application of the present invention is to improve 3D-QSAR (quantitative structure activity relationships). The 3D dynamic structures of several molecules across a drug family determined with the methodology of the present invention are expected to provide a new level of rationalisation to the technique of 3D-QSAR (above that currently produced by traditional computational chemistry methodologies) because the 3D dynamic structures determined from experimental data with the methodology of the present invention will be much more realistic than theoretically-generated conformations.

The present invention thus facilitates the simulation or prediction of the dynamic structure of existing pharmaceutical molecules and will significantly aid the discovery of new drugs by rational drug design and chemical mimicry.

In addition to the above, other technical areas that can benefit from the methods of present invention include:

-   -   1) the generation of biomimetic molecules e.g., the design of         heparin mimetics;     -   2) the analysis of molecular interactions using arrays of         receptor molecules, e.g., in systems biology and proteomics;     -   3) the design of drug-libraries from predictions of likely         reaction routes in combinatorial chemistry; and     -   4) the design and construction of molecular machines         (nanotechnology).

A third aspect of the present invention provides a method for generating data representing an optimised ensemble of three-dimensional structures of a molecule selected from a plurality of ensembles of three-dimensional structures of said molecule, wherein each ensemble is generated according to a method according to the first and/or second aspects of the present invention.

A principal source of real experimental data is nuclear magnetic resonance (NMR) data from organic molecules in aqueous or organic solution, but data from other experimental techniques could also be used. As described more fully below, various NMR experiments can be used synergistically to sample the 3D-structure and dynamic motions of molecules. The data resulting from each NMR experiment is processed using methods particular to each experimental data-type, to prepare it for input into an optimisation algorithm which employs a series of ensembles of molecular structures, each ensemble generated according to the first and/or second aspects of the present invention.

A fourth aspect of the present invention provides a computer implemented method for processing NMR data indicative of the three-dimensional structures of a molecule from an NMR spectrum obtained in respect of said compound, the method comprising:

-   -   a. determining resonance frequencies, v, for resonance multiplet         components in said spectrum;     -   b. identifying resonance multiplet components in said NMR         spectrum which have a difference in resonance frequency (Δv)         that is less than the intrinsic resonance linewidth at half         maximum height, λ, of said multiplet spectrum;     -   c. determining the height, h_(i), of each of i such multiplet         components identified in step b. on said NMR spectrum;     -   d. determining a broadening factor, b, for each multiplet as         follows:

$b = \frac{\lambda}{\lambda - \left( {\Delta \; {v/2}} \right)}$

-   -   e. analysing the multiplet structure to predict ideal resonance         frequencies, v_(ideal), for each of said multiplet components         and determine if the ideal multiplet structure is a doublet or a         triplet;     -   f. if the ideal multiplet structure is a doublet then determine         a scaling factor, ƒ_(i), for each multiplet component as         follows:

ƒ_(i)=2.b

-   -    and determine a height, H_(i), of resonance multiplet         component, i, at 1 mole abundance, as follows:

H _(i) =h _(i)×ƒ_(i)

-   -   g. if the ideal multiplet structure is a triplet then determine         a scaling factor, ƒ_(i(outer)), for each outer multiplet         component as follows:

ƒ_(i)(outer)=4.b

-   -    and determine a scaling factor ƒ_(i(inner)), for overlapped         inner multiplet components as follows:

ƒ_(i(inner))=2.b

-   -   h. determining the height, H_(i), of resonance multiplet         component, i, at 1 mole abundance, as follows:

H _(i(inner)) =h _(i(inner))×ƒ_(i(inner))

H _(i(outer)) =h _(i(outer))×ƒ_(i(outer))

This aspect of the present invention enables data to be derived from NMR spectra to be employed in the optimisation employing molecular ensembles generated according to the first or second aspects of the present invention.

With regard to the first and second aspects of the present invention the data representing the molecule preferably further comprises data indicating a mean angle for said bond. Preferably the data indicating variability of said angle comprises data related to said mean angle. The data indicating the variability of said bond may comprise data indicating a distribution of angles about said mean angle. Said distribution is preferably a probability distribution. Said probability distribution of angles may be symmetric about said mean angle. Preferably the data indicating the variability of said bond is a Gaussian distribution of angles about said mean angle.

In a preferred embodiment the data representing the molecule further comprises further data indicating a further mean angle for said bond. It is preferred that the data indicating variability of said angle comprises further data related to said further mean angle. The data indicating the variability of said bond may comprise a further probability distribution of angles about said further mean angle. Said further probability distribution of angles may be symmetric about said further mean angle. Preferably the data indicating the variability of said bond is a further Gaussian distribution of angles about said further mean angle.

While the first and second aspects of the present invention can be used to generate an ensemble of 3D-structures of a molecule containing a single pair of first and second atoms linked via a bond or sequence of bonds having a particular associated variability, it will be appreciated that the first and second aspects of the present invention is eminently suitable to generate an ensemble of 3D-structures of a molecule containing a plurality of pairs of interconnected first and second atoms, as exemplified below in Examples 1 to 5, in which the molecules subjected to the methods of the present invention each contain a relatively large number of flexible bonds (e.g. see FIGS. 16 and 17 relating to Example 1). Thus, where reference is made below to, “first and second atoms”, it should be understood that any molecule of interest being interrogated using the methodology of the present invention may incorporate one, two or more pairs of “first and second atoms” linked via at least one bond with an associated angular variability.

Regarding the first and second aspects of the present invention the data representing the molecule preferably comprises data indicating the chemical nature of the first and second atoms. The data representing the molecule may further comprise data indicating the variability of said bond based on the chemical nature of the first and second atoms.

Said data indicating the variability of said bond may comprise data indicating that the variability of the bond is zero when the first and second atoms are linked via a double covalent bond, a triple covalent bond or when the first and second atoms are incorporated into an aromatic ring structure.

It may be the case that said data indicating the variability of said bond comprises data indicating that the variability of the bond is zero when one of the first and second atoms is a hydrogen atom or a halogen atom.

Said data indicating the variability of said bond may comprise data indicating that the variability of the bond is zero when the first and second atoms are incorporated into a three or four-membered ring structure.

Said data indicating the variability of said bond can comprise data indicating that the variability of the bond is non-zero and exhibits a unimodal variability of bond angles when the first and second atoms are linked via a single covalent bond and:

-   -   one of the first and second atoms is linked to a third atom via         a double or triple covalent bond; or     -   the first and second atoms are oxygen atoms.

It may be the case that said data indicating the variability of said bond comprises data indicating that the variability of the bond is non-zero and exhibits a bimodal variability of bond angles when the first and second atoms are incorporated into a five or six-membered saturated alicyclic ring structure.

Said data indicating the variability of said bond may comprise data indicating that the variability of the bond is non-zero and exhibits a bimodal variability of bond angles when:

-   -   the first and second atoms are linked via a single covalent bond         and one of the first and second atoms is sp³-hybridised and the         other of the first and second atoms is sp²-hybridised; or     -   the first and second atoms are linked via a single covalent bond         and said single covalent bond is conjugated to at least one         further double covalent bond in the molecule.

Said data indicating variability of said bond may comprise data indicating that the variability of the bond is non-zero and exhibits a trimodal variability of bond angles when the first and second atoms are linked via a single covalent bond and:

-   -   both of the first and second atoms are tetravalent and         sp³-hybridised; or     -   one of the first and second atoms is sp³-hybridised and the         other of the first and second atoms is an oxygen atom.

With reference to the first and second aspects of the present invention it is preferred that said angle is a dihedral angle defined between said first and second atoms.

In a preferred embodiment of the first and second aspects of the present invention the method further comprises predicting at least one experimental parameter from said generated ensemble of three-dimensional structures of said molecule.

Preferably the method further comprises a comparison of said at least one predicted experimental parameter to at least one further parameter derived from at least one physical experiment. That is, an experiment performed on a chemical corresponding to the molecule of interest.

It is preferred that the method further comprises determining an agreement function based on said comparison.

In further preferred embodiments the methods according to the first and/or second aspects of the present invention may further comprise:

-   -   generating further data representing a further ensemble of         three-dimensional structures of said molecule;     -   predicting at least one further experimental parameter from said         further generated ensemble of three-dimensional structures of         said molecule;     -   comparing said at least one further predicted experimental         parameter to said at least one parameter derived from at least         one physical experiment;     -   determining a further agreement function based on said         comparison of the at least one further experimental parameter to         said at least one parameter derived from at least one physical         experiment; and     -   generating data indicating the ensemble having the best         agreement function.

The method may comprise generating a plurality of said further ensembles and selecting the ensemble having the best agreement function determined from said plurality of further ensembles.

Preferably the method further comprises predicting at least two experimental parameters from said generated ensemble of three-dimensional structures of said molecule.

The method may further comprise a comparison of said at least two predicted experimental parameters to at least two further parameters derived from at least two physical experiments. That is, at least two experiments performed on a chemical corresponding to the molecule of interest.

Preferably said at least two physical experiments provide data indicative of the three-dimensional structures of said molecule sampled over different time periods.

Said at least two physical experiments may provide data indicative of the three-dimensional structures of said molecule sampled over different ranges of movement of said molecule.

It is preferred that at least one of said predicted experimental parameters relates to NMR data indicative of the three-dimensional structures of said molecule.

Said NMR data may be selected from the group consisting of scalar-couplings, nuclear Overhauser enhancements (NOEs), rotating-frame NOEs (ROEs), residual dipolar couplings (RDCs), heteronuclear NOEs, and T₁ relaxation data.

The or at least one of said physical experiments may comprise ID NMR spectroscopy. Said ID NMR spectroscopy may be selected from the group consisting of [¹H]-1D spectroscopy, [¹³C]-1D spectroscopy, [¹³C]-filtered [¹H]-1D spectroscopy, [¹⁵N]-1D spectroscopy and [¹⁵N]-filtered [¹H]-1D spectroscopy.

Preferably the or at least one of said physical experiments comprises 2D NMR spectroscopy. Said 2D NMR spectroscopy may be selected from the group consisting of [¹H, ¹H]-DQF-COSY spectroscopy, [¹H, ¹H]-TOCSY spectroscopy, [¹H, ¹³C]-HSQC spectroscopy, [¹H, ¹³C]-HMBC spectroscopy and [¹H, ¹⁵N]-HSQC spectroscopy.

Preferably said molecule is an organic molecule.

Preferably said molecule is selected from the group consisting of a peptide, a carbohydrate, an antibiotic, a nucleic acid, a lipid, a metabolite, a drug molecule and a protein.

Said molecule is preferably selected from the group consisting of hyaluronan, lisinospril and angiotensinI.

Rotatable bonds within the molecule are assigned a number of dynamic parameters, including mean angle values and angle probability distributions about those means. The optimisation algorithm may be used to determine the value for each dynamic parameter that is the best fit to all the real experimental data. By repeated use of the algorithm with modifications to the dynamic parameters and the inclusion of more and more experimental data throughout the optimisation, the mean structure and dynamic motions of the flexible parts of the molecule can be accurately predicted. This methodology is explained in more detail below and demonstrated in Examples 1, 2 and 3 below for three organic molecules, namely a hyaluronan hexasaccharide (an oligosaccharide), lisinopril (a peptidomimetic drug molecule) and angiotensinI (a peptide).

Another aspect of the present invention provides use of an ensemble of three-dimensional structures of a molecule generated according to a method according to the first and/or second aspects of the present invention to predict NMR data indicative of the three-dimensional structures of said molecule.

A further aspect of the present invention provides a method for predicting NMR data using an ensemble of three-dimensional structures of a molecule generated using a method according to the first and/or second aspects of the present invention.

An aspect of the present invention provides use of a method according to the first and/or second aspects of the present invention to an ensemble of three-dimensional structures of a molecule generated according to predict NMR data indicative of the three-dimensional structures of said molecule.

A further aspect of the present invention provides a method for predicting NMR data using an ensemble of three-dimensional structures of a molecule generated using a method according to the first and/or second aspects of the present invention.

Another aspect of the present invention provides a method for simulating a bioactive conformation of a molecule by generating an ensemble of three-dimensional structures of said molecule using a method according to the first and/or second aspects of the present invention.

A further aspect of the present invention provides use of an ensemble of three-dimensional structures of a molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate a bioactive conformation of said molecule.

Another aspect of the present invention provides a method for simulating a conformation of a molecule when bound to its intended target by generating an ensemble of three-dimensional structures of said molecule using a method according to the first and/or second aspect of the present invention.

The present invention further provides, in a further aspect, use of an ensemble of three-dimensional structures of a molecule generated according to a method set out in the first and/or second aspect of the present invention to simulate a conformation of said molecule when bound to its intended target.

In another aspect, the present invention provides a method for simulating a conformation of a ligand molecule when bound to its intended target by generating an ensemble of three-dimensional structures of said ligand molecule using a method according to the first and/or second aspects of the present invention.

A still further aspect of the present invention provides use of an ensemble of three-dimensional structures of a ligand molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate a conformation of said ligand molecule when bound to its intended target.

A yet further aspect of the present invention provides a method for simulating a bioactive conformation of a peptide molecule by generating an ensemble of three-dimensional structures of said peptide molecule using a method according to the first and/or second aspects of the present invention.

The invention further provides, in another aspect, use of an ensemble of three-dimensional structures of a peptide molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate a bioactive conformation of said peptide molecule.

A further aspect of the present invention provides a method for simulating a bioactive conformation of a carbohydrate molecule by generating an ensemble of three-dimensional structures of said carbohydrate molecule using a method according to the first and/or second aspects of the present invention.

The invention further provides, in another aspect, use of an ensemble of three-dimensional structures of a carbohydrate molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate a bioactive conformation of said carbohydrate molecule.

A further aspect of the present invention provides a method for simulating a bioactive conformation of a drug molecule by generating an ensemble of three-dimensional structures of said drug molecule using a method according to the first and/or second aspects of the present invention.

The invention further provides, in another aspect, use of an ensemble of three-dimensional structures of a drug molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate a bioactive conformation of said drug molecule.

An aspect of the present invention relates to a method for simulating the hydrogen bond occupancy in a molecule by generating an ensemble of three-dimensional structures of said peptide molecule using a method according to the first and/or second aspects of the present invention.

There is further provided, according to another aspect of the present invention, use of an ensemble of three-dimensional structures of a molecule generated according to a method set out in the first and/or second aspects of the present invention to simulate the hydrogen bond occupancy of said molecule.

According to a still further aspect of the present invention there is provided a data carrier carrying data usable to generate an ensemble of three-dimensional structures of a molecule, the molecule comprising first and second atoms linked by at least one bond, the data comprising data representing said molecule including data indicating variability of said angle.

A yet further aspect of the present invention provides a carrier medium carrying computer readable instructions configured to cause a computer to carry out a method according to the first and/or second aspects of the present invention.

According to another aspect of the present invention there is provided a computer apparatus for generating data representing an ensemble of three-dimensional structures of a molecule, the apparatus comprising:

-   -   a memory storing processor readable instructions;     -   a processor configured to read and execute instructions stored         in said memory;     -   wherein said processor readable instructions comprise         instructions configured to cause the processor to carry out a         method according to the first and/or second aspects of the         present invention.

The starting point for generating a molecular ensemble according to the first and/or second aspects of the present invention is a description of molecular topology, which is dictated by the chemical formula of the molecule of interest and describes the number and type of bonds, their lengths, angles and torsional (dihedral) angles between them. This geometrical information can be conveniently described by a set of internal coordinates (also commonly known as a Z-matrix) [1]. The internal coordinates provide a description of each molecular atom in terms of bond lengths, bond angles, and dihedral angles, relative to other adjacent atoms. These internal coordinates can be used to specify a set of molecular (Cartesian) coordinates for the atoms in space, using standard geometrical arguments [2].

Due to the nature of covalent chemical bonds (e.g., σ-bond, π-bond) and orbital hybridisation (sp², sp³), in the majority of cases bonds and angles can be assumed to maintain their average geometry while a molecules undergoes local dynamic motions in solution (to a good approximation), i.e., they can be kept constant. Therefore, to a first approximation local dynamic motions of molecules in solution occur by rotations about dihedral angles (see FIGS. 1 a and 1 b). Furthermore, these rotations usually occupy a limited set of possible angles about a mean angle (which will be described in more detail later), that is, the range of angles which a flexible bond can adopt can be characterised by defining a variability in bond angle associated with that bond.

A molecular ensemble of 3D-structures generated according to the first and/or second aspects of the present invention is a set of discrete molecular structures (which in itself is a set of atomic coordinates) that is intended to mirror as closely as possible the range of 3D-shapes that a solvated molecule undergoes while flexing. In a preferred embodiment of the present invention, a molecular ensemble is generated by varying specified dihedral angles (those that can rotate, also known as conformational degrees of freedom) according to well-established models of molecular motion, while keeping other conformational degrees of freedom fixed (angles, bonds and non-rotatable torsions). Examples of conformational degrees of freedom are glycosidic, phosphodiester and peptide backbone dihedral angles. A series of rules relating to the dynamic behaviour of specific types of bonds in solution has been developed by the inventors and is set out below. These rules are used to establish which bonds in a molecule of interest are allowed to rotate and those which are not. Whether a bond should be allowed to rotate can be determined with the following considerations:

-   -   1) all single bonds within the molecule are rotatable, whereas         no double-, triple- or aromatic bonds are rotatable;     -   2) the rotation of many single bonds has no effect on the         relative positions of atoms in the molecule, and therefore these         kinds of single bonds do not need to be rotated. Examples of         such single bonds include bonds between a hydrogen atom and any         other atom, or a halogen atom and any other atom; and     -   3) single bonds within some cyclic chemistries are unable to         rotate because of the constrained geometry; an example of this         would be the C—C bonds in cyclopropane.

For small librations (oscillations about a mean angle) of a dihedral angle, the molecular potential energy may be considered harmonic (i.e., depends on the square of the angular deviation from the mean) [3]. The distribution of angles about the mean from such a potential may be modelled using a Gaussian (also known as Normal) distribution (see FIG. 1 c), although it will be appreciated that other models of bond angle variability may be adopted.

Once the chemical structure of the molecule of interest has been analysed and the appropriate conformational degree(s) of freedom of the molecule identified using standard methods together with the rules set out above, where appropriate, it is then necessary to establish a set of initial parameters to describe each bond within the molecule. By way of example only, the most simple case of a molecule of interest including only a single variable dihedral angle will be considered. In this case, the dihedral angle is allocated a mean bond angle (e.g. 40°) and a maximum variability in bond angle about the mean angle (e.g. 18°). The dihedral angle being modelled will therefore possess a mean value of 40° but can in fact vary between 22° and 58° across an ensemble of structures generated for that molecule. If the ensemble size is taken as, say 10, in this simple example, then when the ensemble is generated, it will consist of 10 discrete molecular structures, each structure including a specific value for the variable dihedral angle of between 22° and 58°, with the overall mean of all of the dihedral angles being 40°. The distribution of dihedral angles across the range from 22° to 58° is preferably controlled with use of some form of distribution function, such as a Gaussian probability distribution function. While a preferred embodiment of the present invention uses a canonical Gaussian spread of angles (equation (1)) other distributions could be readily implemented. Examples of other distributions include the top hat function (equation (2)) and the Weibull distribution (equation (3)).

$\begin{matrix} {{p\left( {{x;\mu},\sigma} \right)} = {\frac{1}{\sigma \sqrt{2\; \pi}}{\exp \left( \frac{\left( {x - \mu} \right)^{2}}{2\; \sigma^{2}} \right)}}} & (1) \\ {{{p\left( {{x;\mu},\sigma} \right)} = {{{\frac{1}{\sigma}\mspace{14mu} {for}\mspace{14mu} \mu} - {{1/2}\; \sigma}} \leq x \leq {\mu + {{1/2}\; \sigma}}}},{{otherwise} = 0}} & (2) \\ {{p\left( {{x;k},\lambda} \right)} = {\frac{k}{\lambda}\left( \frac{x}{\lambda} \right)^{k - 1}\exp \left\{ {- \left( \frac{x}{\lambda} \right)^{k}} \right\}}} & (3) \end{matrix}$

In the preferred embodiment where the angular probability distribution is modelled as a Gaussian distribution, the distribution would be p(α)=G(μ, σ), which is a Gaussian distributed angle (α) with mean angle μ (average bond geometry) and a standard deviation angle of σ (local libration), representing a single degree of freedom, see FIG. 1( c). This probability distribution will simulate libration about a single bond that corresponds to a 3D-distribution around a single conformer, see FIG. 2 for an example based on angiotensin-4, with zero, one and two degrees of freedom.

In commonly encountered sp² and sp³ bond chemistries (planar and tetrahedral, respectively) there may be several distinct conformational states (e.g., alkane chains that can adopt g+, g− and t rotamer conformers at each carbon-carbon bond, cyclic rings that can adopt a range of conformations such as chair, boat and/or skew boat conformations, and functional groups, such as peptide bonds, which can adopt slowly-interconverting cis and trans conformations). In such cases, more complicated and more general expressions may be used for the probability distribution, such as p(α)=p₁G(μ₁, σ₁)+p₂G(μ₂, σ₂)+p₃G(μ₃, σ₃), which corresponds to a system with up to three librational states, where p₁, p₂ and p₃ are probabilities such that p₁+p₂+p₃=1 (specific examples are described in detail below). Furthermore, some of the probabilities and/or mean and standard deviation values may be coupled to one another, in order to model such cases as found in, e.g., peptides or puckering cyclohexane-type rings. For example, σ₁=σ₂=σ₃ (in the equation above) would indicate that each conformational substate has an identical range of librational motion.

Calculation of a dynamic ensemble in this manner may result in parts of the molecule accidentally clashing with one another. In order to avoid this situation, after generation of each single structure (within the ensemble) it may be tested to see whether any of the van der Waals active atoms (see below) are within a set distance (typically 0.1 nm). If this condition is met the 3D-structure can be deleted and recalculated. This process may be repeated until a sterically-acceptable 3D-structure is generated (up to a maximum number of tries, typically 50 times, after which the current 3D-structure is automatically accepted).

Once an ensemble of molecular structures has been generated it may be used to predict real experimental data, for example, but not limited to NMR data. The quality of the prediction, i.e. the closeness of fit of the predicted experimental data to the real experimental data, may then be used to assess how closely the ensemble of structures models the range of structures that the real molecules populate in solution.

It will be appreciated that it is theoretically possible to calculate more measurable molecular properties from a dynamic molecular ensemble than it would be from a static representation (assuming that a relevant physical theory correlating the two is known). This is a basic hypothesis of classical statistical physics, which says that a full description of a molecular system includes the states that it can occupy (macrostates) and the probability of their occurrence (statistical weights) [4]. Thus, in contrast to using just a single mean angle to represent each rotatable bond as in prior methods, the inclusion of a degree of variability at each conformational degree of freedom makes it is possible to simultaneously satisfy one or more different kinds of NMR experimental data, which each provide a different snapshot of the molecular flexibilities because they are averaged from the ensemble over different functions of molecular geometry, effectively increasing the amount of experimental information available to define the model. This facilitates the use of multiple NMR datasets, which allows the large number of restraints that are often necessary to define the conformation of dynamic molecules.

When a comparison to real experimental data is to be made, a molecular ensemble of structures is first generated according to the first and/or second aspects of the present invention. Standard methods (explained in more detail below) are then used to predict an experimental parameter for each member of the ensemble. The predicted values for each member of the ensemble are then averaged and the average value compared to the corresponding parameter derived from the real experimental data.

For example, nuclear Overhauser enhancements (NOEs) are known to average over distances raised to the power six. Standard methods may therefore be employed to determine a predicted NOE value for each member of the ensemble, this set of predicted NOEs averaged and this average value compared to the NOE calculated from the real experimental data. Further examples include residual dipolar couplings which average over squared cosine angles and scalar couplings which average over torsional angles.

Following the prediction of experimental parameters and the comparison of said predicted parameters to corresponding real parameters, one or more further ensembles can be generated according to the first and/or second aspects of the present invention and each further ensemble tested against the real experimental data in a similar manner as described above. In this way, an optimisation routine can be established (see FIG. 3) in which a series of ensembles of molecular structures are iteratively generated and compared to real experimental data to determine the ensemble which most closely matches the real experimental data, that is the ensemble which exhibits the highest correlation with the real experimental data.

At the heart of the algorithm is a conformational model generator that produces a dynamic molecular ensemble for each and every iteration of an optimisation routine. The generator derives the ensemble from a set of variable parameters (some that define conformation, while others define dynamic spread) as outlined above and described in more detail below. These parameters are then simultaneously optimised to fit real experimental data derived from one or more than one type of experiment (which preferably contain different kinds of NMR data), resulting in a best-fit dynamic ensemble for the molecule using the Monte-Carlo approach [5]. This process can be described algorithmically in the following way, which permits its implementation on a digital computer:

-   -   1) Generation of a dynamic ensemble based on the conformational         degrees of freedom by a set of dynamic molecular variables. The         conformational degrees of freedom are selected based on local         chemistry considerations (see definitions later). In particular,         the types and hybridisation of chemical bonds determine whether         they will be rotatable.     -   2) Prediction of experimental data from the dynamic ensemble by         use of a suitable physical theory and integration (averaging).         By way of example, for the NMR experiments considered in detail         below (nuclear Overhauser enhancement experiments (NOESY,         ROESY), residual dipolar couplings, coupling constants and         ¹H-¹⁵N heteronuclear enhancements) suitable physical theories         have been derived and validated [6, 7-9].     -   3) Comparison of the predicted experimental data against the         true experimental data and calculation of an agreement function.         This is normally the square distance between the two (including         experimental error), referred to as χ².     -   4) If the χ² is lower than that seen previously, this dynamic         structure is accepted and becomes the new candidate best         structure.     -   5) The molecular variables are changed randomly (both mean and         dynamic spread) and we jump back to step 1 until a specified         number of iterations have elapsed. The number of steps required         is dependent on the complexity of the problem. In simple terms,         this complexity can be estimated from the number of         conformational degrees of freedom.     -   6) Once a suitable number of iterations have been performed,         such that a well-defined final ensemble can be generated         reproducibly, the current candidate structure represents a         single solved dynamic structure. This structure can be assessed         for goodness-of-fit to the experimental data by calculating the         average χ² per conformational restraint.     -   7) Many dynamic structures are generated and statistics are         performed on them to determine the precision of the repeated         structure determination. This determines the robustness of the         experimental data in determining a single unique dynamic         molecular conformation.

The chi-square least-squares measure (χ²) is used to determine the goodness of fit between the experimental data (x_(exp)) and the theoretical predictions (x_(pred)), which is the sum of the square distances between prediction and experiment, divided by the square of the estimated error (ε² _(exp)) on each experimental measurement. Three measures are discussed herein, the least-squares fit for each individual restraint (χ² _(restraint)), sums of these values to make the least-squares fit for a dataset (χ² _(dataset)) and sums of these values to make the least-squares fit for all experimental data (χ² _(total)), see equations (4-6).

$\begin{matrix} {\chi_{restraint}^{2} = \frac{\left( {x_{\exp} - x_{\exp}} \right)^{2}}{ɛ_{\exp}^{2}}} & (4) \\ {\chi_{dataset}^{2} = {\sum\limits_{restraint}\; \chi_{restraint}^{2}}} & (5) \\ {\chi_{total}^{2} = {\sum\limits_{dataset}\; \chi_{dataset}^{2}}} & (6) \end{matrix}$

At each iteration of the algorithm, the current dynamic molecular ensemble is used to make a prediction of one or more experimental data sets, which ideally average the ensemble over different functions of the molecular geometry (as discussed above). The χ² fit of each data point is reported, from which statistics for each different kind of dataset can be calculated (exemplified in Examples 1, 2 and 3 below).

The mean, their spreads (also referred to herein as variability) and relative probability weightings of the Gaussian distributed angles are iteratively searched by repeated calculation of the dynamic molecular ensemble and comparison with experimental data, until a good fit to the experimental data is found (FIG. 3). In a preferred embodiment of the present invention, a Monte-Carlo iterative approach has been using to perform this search, but other iterative optimization procedures can also be used, such as, but not limited to the Levenberg-Marquardt algorithm or a Genetic algorithm.

Certain classes of molecular restraints can be added to the calculation that are not dependent on experimental data, but instead are regarded as fundamental molecular properties. The most obvious is the van der Waals energy, which can be implemented as a direct addition to χ². The actual numerical value for the van der Waals force constant should be modified by a constant scaling factor (see below) chosen by the user so that it harmonises with the other experimental datasets.

In the following description examples of NMR experimental data that are sensitive to dynamic conformation are given, which will be used in Examples 1, 2 and 3 below and can be used to determine the dynamic structure of a variety of molecules, in particular organic molecules. The way in which the NMR experiments are performed and NMR datasets acquired is also described in detail below. Furthermore, the theory used to make predictions of these experimental NMR parameters is described, and how the structures are optimised by comparing experimental measurements against predictions. NMR is a particularly suitable method because it provides atomic-scale information in aqueous solution. However, it should be noted that other types of experimental data (that provide dynamic information) could be used, such as solution-state scattering and fluorescence energy transfer (specific examples of their use are not detailed in this application).

The first type of experimental data to be considered is produced by NMR experiments that are based on the nuclear Overhauser effect [10]. In this case, particularly useful experiments are NOESY and ROESY spectroscopy. An important advancement over standard NMR structure-calculation methods is the use of a full relaxation matrix [7] to theoretically predict the experimental data. Such a calculation method (as opposed to using the approximation of simply relating intensity to distance, r, through r⁻⁶) is important because small molecules can contain many NMR-active nuclei in a small volume and mixing times are often relatively long. Therefore, there is the strong possibility of significant spin-diffusion, which can only be taken into account by calculation of a full relaxation matrix. Methods for performing this calculation by matrix diagonalisation have been published previously [7]. Ultimately, cross-peaks are represented by off-diagonal terms in the final matrix, while diagonal-peaks are found on the diagonal of the matrix. Different linear combinations of spectral density functions can be used to perform calculations of the different possible relaxation experiments (e.g., NOESY, ROESY and T-ROESY).

Other types of NMR relaxation experiments, such as heteronuclear T₁-relaxation and NOE data (typically between ¹H and ¹³C or ¹⁵N), can be interpreted as order parameters (S²), overall tumbling correlation times (τ_(c)) and internal correlation times (τ₁), as described previously [8]. These data are intimately related to local dynamics and can be used as a complement to other NMR measurements. In order to make predictions, all structures in the molecular ensemble may be overlaid such that they have the minimum root-mean-square deviation (RMSD) between them. The correlation functions for selected vectors are calculated in this molecular frame, which have been derived previously [11], resulting in an estimation of S².

NMR scalar coupling constants (J), and in particular three-bond couplings, are indicative of conformation via an empirical relationship, the Karplus curve [12]. For each dihedral angle, assuming that the Karplus equation is known, it is possible to calculate J by averaging over the dynamic ensemble and then directly comparing to the experimental data to determine χ².

Residual dipolar couplings (RDCs) induced by an inert weakly-alighning co-solute can be calculated by methods that have been derived previously [7]. Other methods are available in the literature for the more generic case [13]. RDCs are an important complement to the total experimental data pool because they provide long-range conformational information rather than local information provided by relaxation data. Some data (e.g., scalar couplings) is directly comparable with theoretical calculations. However, in other cases (e.g., NOESY measurements) datasets need to be scaled by an arbitrary constant, which is dependent on sample concentration, spectrometer sensitivity etc. and can be calculated from the experimental data and their respective prediction by a straight-line fit (passing through zero). A suitable coefficient (κ_(dataset)) is shown in equation (7) and can be applied to all predictions such that a graph of {κx_(pred), x_(exp)} has a unitary gradient (see below).

$\begin{matrix} {\kappa_{dataset} = \frac{\sum\limits_{dataset}\frac{x_{pred}x_{\exp}}{ɛ_{\exp}^{2}}}{\sum\limits_{dataset}\frac{x_{pred}^{2}}{ɛ_{\exp}^{2}}}} & (7) \end{matrix}$

An important consideration in equation (7) is the strong dependence on errors. If these are not quantified correctly then the resultant structure may be biased. While calculation of the experimental error (ε_(exp)) has been discussed above, errors due to the finite size of the ensemble has not. One case where this is particularly important (it is not considered for NOESY, ROESY or scalar couplings) is in making predictions of RDCs, which depends on the direction of the inter-nuclear vector within the molecular frame. Here the dependence on angle is highly non-linear and thus an extra error correction has to be applied. This is most suitably achieved by scaling the effective error. The scaling (to produce an effective error ε_(exp)′) can be derived in the following way. If θ is the angle between the major axis of alignment in the molecular frame, then starting from the equation defining residual dipolar couplings [13], equation (8) is obtained, which allows the calculation error to be obtained by differentiations, equation (9). Suitable approximations result in equation (10).

$\begin{matrix} {{RDC} \propto {{\cos^{2}\theta} - 1}} & (8) \\ \begin{matrix} {{{Calculation}\mspace{14mu} {error}} = {{\frac{}{\theta}\left( {{\cos^{2}\theta} - 1} \right)}}} \\ {= {{2\; \sin \; \theta \; \cos \; \theta}}} \\ {= {{\sin \; 2\; \theta}}} \\ {\approx {\frac{1}{2}\left( {1 - {\cos \; 4\; \theta}} \right)}} \end{matrix} & \begin{matrix} (9) \\ \; \\ \; \\ \; \\ (10) \end{matrix} \end{matrix}$

Substituting the identity: cos 4θ=8 cos⁴θ−8 cos² θ+1 into (10) and dividing this into the experimental error, results in equations (11) and (12), the latter of which is almost identical to equation (11), but avoids division by zero by having a minimum value of ¼ in the denominator and is therefore used in practice.

$\begin{matrix} \left. \Rightarrow{ɛ_{\exp}^{\prime} \approx \frac{ɛ_{\exp}}{4\left( {{\cos^{2}\theta} - {\cos^{4}\theta}} \right)}} \right. & (11) \\ \left. \Rightarrow{ɛ_{\exp}^{\prime} \approx \frac{ɛ_{\exp}}{0.25 + {3\left( {{\cos^{4}\theta} - {\cos^{2}\theta}} \right)}}} \right. & (12) \end{matrix}$

Using equation (12), it is possible to increase the total experimental error estimate (ε_(exp)) to take into account errors associated with predictions of residual dipolar couplings, which can then be used to more-accurately assess the degree of fit with the experimental data.

A preferred embodiment of the present invention will now be described which will serve to further describe various preferred features of the present invention.

Before a first ensemble can be generated for a molecule of interest and structure calculations performed based on said ensemble, a variety of parameters are specified.

A series of solvent masks are specified for the molecule in each solvent used in the real experiments from which datasets of real experimental data have been derived. This comprises a list of hydrogen atoms that are NMR-active and inactive due to rapid exchange with the solvent. This information is important for the accuracy of the full-relaxation matrix calculation used in the calculation of NMR relaxation predictions (see above), which is very sensitive to the exact location of every proton in the molecule. All protons in the molecule that are NMR-inactive due to chemical exchange with the solvent must therefore be excluded from the calculations. For example, the solvent mask for a carbohydrate in H₂O would specify that all hydroxyl hydrogen atoms are NMR-inactive, but for the same carbohydrate in DMSO, the solvent mask would specify that the same hydroxyl protons are active. Each dataset has the appropriate solvent mask associated with it as an input parameter.

First the number of solvents required is specified, followed by the required number of solvents, listed by name (these are used later by the experimental data input files). The actual atoms that are included or excluded from the solvent mask are specified by either an add statement or an exc statement, which add atoms to the solvent mask or takes them away. The next two fields in each of these statements define the residue number and atom types. A wild-card asterisk is used to select all protons (H*) and take away all hydroxyls (HO*). A typical file is shown below:

conditions: solvents 2 endsection solvent: name h2o add * H* exc * HO* endsection solvent: name d2o add * H* exc * HO* exc * H2N endsection

A van der Waals mask is prepared according to the needs of the structure calculations, which is a global parameter set (i.e., is not specific to a particular dataset). This mask allows atoms to remain NMR-active but to be effectively transparent to van der Waals forces (calculated as an addition to χ², see below), allowing them to overlap and clash with other portions of the molecule without penalty during structure calculations. The use of this mask is important in allowing atoms within the structure of undetermined orientation but arbitrary initial (and/or fixed) geometry to not bias the result from the structure calculations by unfortunate steric clashes. Examples of this case are hydroxyl protons and carboxylate group oxygen atoms, whose conformations cannot be easily investigated experimentally in water. This mask can also be used in the initial stages of 3D-structure determination, when one set of dynamic variables can be tested independently of another, by uncoupling them from another portion of the structure by allowing that other portion of the structure to adopt conformations and steric clashes without penalty. As the dynamic structure of the molecule is progressively defined, the van der Waals mask is appropriately updated, i.e., including all portions of the molecule that have currently been solved.

In the configuration section of the van der Waals input file the cut-off distance for calculation is specified (atoms that are separated by one or two covalent bonds are always excluded from the calculation) and a coupling constant is specified, which determines the scaling factor applied to the van der Waals calculation before it is included as a term in the overall χ² calculation. The next section (the nonbonded section) defines the atomic radii and repulsion energy for each kind of atom (e.g. for hydrogen, vdw*H*0.016 0.60). Following this, a series of statements are listed detailing the atoms that are included and those that are excluded (without any statements all atoms are included). In the example input file shown below all the hydroxyl atoms are excluded (exc*HO*), while all other atoms are included. The nomenclature used in this specification is similar to that used in the solvent masks.

configuration: vdw.cutoff 6.0 vdw.coupling 1e−4 endsection nonbonded: vdw * H* 0.016 0.60 vdw * C* 0.100 1.91 vdw * N* 0.170 1.82 vdw * O* 0.210 1.66 exc * HO* endsection

For prediction of NMR relaxation data (NOESY, ROESY, T-ROESY) via the model-free approximation [11], a value must be specified for the molecular correlation time (τ_(c)) at 298 K and 0.88 cP viscosity (i.e., H₂O at 25° C.), which is a global parameter. The value of τ_(c) can be determined experimentally [8] or estimated in the first instance. To a reasonable first approximation, small molecules of molecular weight ˜400 Da have a correlation time of 0.4 ns at 298 K, whereas a small protein of ˜10 kDa has a correlation time of ˜5 ns at 298 K. Occasionally, molecules are of sufficiently low molecular weight (around ˜250 Da) that the NOE cross-peaks pass the threshold from being negative (normal for proteins) to positive (i.e., they have the opposite sign to the diagonal peaks), which allows τ_(c) to be estimated through the equation τ_(c)ω˜1.12 (the value of τ_(c) that causes the NOE cross-peaks to be zero, where ω is the proton-resonance angular frequency). It should be noted that ROEs do not have this zero point and thus can be very useful when τ_(c)ω˜1.12 [9].

The calculation of the spectral density used in prediction of relaxation data can be improved for molecules with a highly-anisotropic shape, by introducing a symmetric top model for molecular diffusion. In this case the single |_(c) value is replaced by two correlation times (parallel and perpendicular to the axis of symmetry on the symmetric top). The resulting modifications to the spectral density function is described in [46], equations (3) to (9).

When the value for τ_(c) has not been determined experimentally, the initial estimated value can be reviewed after a few rounds of structure calculations (should this be deemed necessary), at the point when it is clear that the dynamic structure starts to have a good correlation with the experimental data. At this point, the τ_(c) value can be optimised by repeated calculations with the same datasets, but with different values of τ_(c) and taking the value that gives the best χ² _(total) value to the experimental data.

While the value of τ_(c) is a global physical parameter that is fixed during structure calculations, variations in the actual value of τ_(c) in datasets due to differences in solvent viscosity (e.g., 100% D₂O has ˜1.25 the viscosity of 100% H₂O) or temperature (e.g., one relaxation dataset may have been recorded at 298 K, while another was at 278 K) is compensated for by using the simple Debye theory for rotational diffusion, which states that the value of τ_(c) is proportional to the temperature and inversely proportional to the solvent viscosity. Each relaxation dataset therefore has both a value for the NMR sample's viscosity (in cP) and the temperature at which the dataset was acquired (in K). The viscosity (ζ) of 100% H₂O at different temperatures (T1, T2; ζ₂₉₈ of 100% H₂O=0.0088 P) can be calculated using equation (13). The viscosity of 100% D₂O at a given temperature is related to that of 100% H₂O via equation (14). By using equation (13) and linearly scaling equation (14) to a given percentage v/v of H₂O/D₂O, the viscosity of H₂O/D₂O mixtures at any given temperature can be estimated.

ζ_(T2)=ζ_(T1) ×e ^((1/T1-1/T2))  (13)

ζ_(D) ₂ _(O)=1.23×ζ_(H) ₂ _(O)  (14)

In the preferred embodiment described here, experimental data is input into the structure calculations via a series of text files that contain specific measurements, information about spectral overlaps and physical parameters that describe the experimental conditions. In all files a configuration section specifies the NMR magnetic-field strength (field 900 MHz), a name identifier for the dataset (ident NOESY) and the appropriate solvent mask to use (h2o). In the case of a relaxation dataset, the temperature (temp 298, in Kelvin), the solvent viscosity (visc 0.88, in cP) and the mixing time used (mixtime 400 ms) are also specified. An example input file specifying NOESY data is described below:

configuration: field 750 solvent h2o ident NOESY temp 298 visc 0.88 mix_time 400 ms endsection data: asgn 1 a 6 H1M a 6 H2N 48.8 19.6 0 ovlp 1 a 6 H2M a 6 H2N 48.8 19.6 0 ovlp 1 a 6 H3M a 6 H2N 48.8 19.6 0 asgn 2 a 6 H3 a 6 H2N 34.2 13.7 0 . . . endsection

The experimental data section has a format that is somewhat standard, but is also tailored to the specific type of experimental measurements. For example, in the NOESY data-input file above, the line asgn 2 a 6 H3 a 6 H2N 34.2 13.7 0 specifies restraint number 2, while the subsequent four fields define the two atoms, between which the NOE is observed (and should be calculated). The next two fields give the restraint intensity and its error (in the case of asgn 10, 34.2±13.7) and the final field is a flag (0) specifying that the χ² _(restraint) value (comparison of the predicted value of this restraint to the experimentally-observed value) should be included in the total χ² _(total) value for the dynamic ensemble (a value above 5 would indicate that it should not be used). Overlapped restraints are specified with the format ovlp 1 a 6 H2M a 6 H2N 48.8 19.6 0, where ovlp 1 indicates that the NOE between the atoms in this overlapped restraint needs to be combined with the NOE calculated from the primary restraint of the same number (i.e., asgn 1). Diagonal peaks in the spectrum are simply represented as NOEs between the same two atoms (see actual input data-files in Appendix A for examples of this).

configuration: field 900 solvent h2o ident RDC endsection data: asgn 1 a 6 C1 a 6 H1 −5.85 0.35 0 . . . endsection

The configuration section of a residual dipolar coupling (RDC) input file is directly analogous to that described above for relaxation data, see the example input file above. In the line asgn 1 a 6 C1 a 6 H1 −5.85 0.35 0, asgn 1 specifies that this line is restraint number 1. The subsequent a 6 C1 a 6 H1 characters define the two atom assignments, between which the residual dipolar coupling is to be calculated. Following this, the experimental measurements and their errors are listed (i.e., in the case of asgn 1, −5.85, 0.35 Hz) and a flag (0) specifying that the χ² _(restraint) value of the comparison of the predicted value of this restraint to the experimentally observed value should be included in the total χ² _(total) value for the dynamic ensemble (as described above).

configuration: field 900 solvent h2o ident JCOUP endsection data: coup 1 2 H2 2 C2 2 N2 2 H2N 9.45 −2.08 0.63 0 9.67 0.5 0 endsection

Input data-files representing conformation-dependent scalar-couplings are similarly specified. A typical input file is shown directly above. In the line: coup 1 2H2 2 C2 2 N2 2H2N 9.45 −2.08 0.63 0 9.67 0.5 1, coup 1 specifies that this structural restraint is a coupling-constant type of data and is restraint number 1. The four fields: 9.45-2.08 0.63 0 specify the A, B and C and phase (φ) parameters to use in the generic Karplus equation ³J_(HH)=Acos²(θ+φ) BCOS(θ+φ)+C, for the HCNH angle θ. Following this, the experimental measurement and its error is given (in the case of coup 1, 9.67±0.5 Hz) and a flag (0) specifying that the χ² _(restraint) value of the comparison of the predicted value of this restraint to the experimentally observed value should be included in the total χ² _(dataset) value for the ensemble (described above)

Dihedral angle structural restraints for peptides can be generated using chemical shifts and the program TALOS [42]. The program TALOS takes as input the peptide sequence and the chemical shifts for HN, HA, C, CA and CB nuclei for each residue within the molecule and outputs a predicted value with error for each backbone phi and psi angle. Since TALOS is actually designed for proteins, which are generally more rigid than peptides, the errors actually used for the χ² calculation are taken as twice the error values predicted by TALOS (this value is based upon our current experience). An example format for a dihedral angle structural restraint file is as follows:

configuration: remark Angiotensin1, dihedral angle restraints remark given twice the error value from TALOS field 600 solvent h2o temp 298 visc 0.88 ident TDIHEDRALS endsection data: remark dihedral_no dihedral_atom_identifiers(x8) angle error code remark phi example dihe 1 1 C 2 N 2 CA 2 C −85 26 0 remark psi example dihe 9 2 N 2 CA 2 C 3 N 138 36 0 remark omega example dihe 17 3 CA 3 C 4 N 4 CA 180 20 0 endsection

In this file, the configuration: section follows the same format as other data types. In the data: section, each restraint is introduced by dihe and the subsequent field is the restraint number. The next 8 fields define the 4 atoms in the dihedral angle, in pairs of (residue number, atom name). Following these, the dihedral angle value is given and then its error.

The presence or absence of hydrogen bond interactions can be inferred from several kinds of experimental data, including amide proton exchange rates and temperature coefficients. Whether a hydrogen bond can be considered to be present or not depends on both angular and distance criteria. Typically the donor and acceptor electronegative atoms are separated by a distance of between 3.3 to 2.5 angstroms, the donor hydrogen and acceptor electronegative atoms by a distance of 2.5 to 1.5 angstroms and the angle between the three atoms is >110°. If all these three criteria within a structure are satisfied, a hydrogen bond can be considered to be present. In a flexible molecule, hydrogen bonds can be transiently formed and broken, giving them a percentage occupancy that may be estimated from experimental data (see [36]). By counting the number of molecules within the current best ensemble that satisfy these criteria, the percentage occupancy of the hydrogen bond within the ensemble can be calculated. Comparison of the calculated occupancy for the current ensemble with the experimental restraint occupancy value allows a χ² _(restraint) score to be directly calculated.

An example format for a hydrogen bond structural restraint file is as follows:

remark hydrogen bond restraints file configuration: solvent h2o ident HBOND endsection data: remark atomsx3 d1 range d2 range ang percent perc_error start code hbond  1 3 N 3 HN 1 OD1 2.9 0.4 2.0 0.5 110 0 10 0.0 0 hcomb 1 3 N 3 HN 1 OD2 endsection

In this file, the configuration: section follows the same format as other data types. In the data: section, each restraint is introduced by hbond and the subsequent field is the restraint number. The next 6 fields define the 3 atoms in the hydrogen bond (electronegative donor, hydrogen atom, electronegative acceptors, respectively), in pairs of (residue number, atom name). Following these, the next 5 fields specify the three criteria to judge by whether a hydrogen-bond is present in a structure or not. The first 2 values give a mean distance and range (e.g. for hbond 1, 2.9±0.4 angstroms) between which the two electronegative atoms must be found, the next 2 values give a mean distance and range between which the hydrogen and acceptor atoms must be found, and the last value is a minimum value for the angle between all three atoms. The next two values define the expected percentage occupancy and error of the hydrogen bond determined from the experimental data (e.g. for hbond 1, 0 and 10, meaning 0±10% occupancy). The last two fields define the point during each run of calculations at which the restraint is included in the χ² _(total) score and the quality code, respectively. In cases where the hydrogen-bond acceptor atom can be more than one atom, other acceptor atoms can be included into the cumulative score for a restraint with lines beginning with hcomb, which behaves in an identical manner to the ovlp lines used in NOESY datasets (e.g., for hbond 1 in the example above the total occupancy of all hydrogen bond interactions for the amide proton of residue 3 with the two sidechain oxygen OD atoms of residue 1 should be 0±10).

configuration: solvent h2o ident ORDER endsection data: hnoe 1 w 2 H2N w 2 N2 0.44 0.01 0 endsection

Order parameters (which are the result of Lipari-Szabo model-free analysis) are useful descriptors of local dynamics and a specific implementation and input datafile is described here. The configuration section of this input file is directly analogous to those described previously and an example is presented above. In the experimental data section the line hnoe 1 w 2 H2N w 2 N2 0.44 0.01 0, hnoe 1 specifies that this structural restraint is an order-parameter type of data and is restraint number 1. The subsequent fields: w 2 H2N w 2 N2 define the two atoms assignments, for which the order parameter is to be calculated. Following this, the experimental measurements and their errors are given (in the case of hnoe 1, 0.44±0.01) and a flag (0) specifying that the χ² _(restraint) value of the comparison of the predicted value of this restraint to the experimentally observed value should be included in the total χ² _(dataset) value for the dynamic ensemble (as described above).

In order to correctly calculate an ensemble of 3D-structures, the dynamic model for the molecule must be specified, which is another global parameter set. This dynamic model contains all the specifications for the variables of the rotatable bonds of interest within the molecule. Whether a bond should be allowed to rotate can be determined with the following considerations:

-   -   1) all single bonds within the molecule are rotatable, whereas         no double-, triple- or aromatic bonds are rotatable;     -   2) the rotation of many single bonds has no effect on the         relative positions of atoms in the molecule, and therefore these         kinds of single bonds do not need to be rotated. Examples of         such single bonds include bonds between a hydrogen atom and any         other atom, or a halogen atom and any other atom; and     -   3) single bonds within some cyclic chemistries are unable to         rotate because of the constrained geometry; an example of this         would be the C—C bonds in cyclopropane.

Single bonds within the molecule that have been identified to require a dynamic model (in accordance with the above considerations) are now assigned a unimodal, bimodal or trimodal model. When there is no experimental data indicating the modality of the bond in question, the choice of modality of the dynamic model is determined using Table 1. This table shows the relationship between the bond modality to be used and the hybridisation state [14] of the two atoms in the single bond (atoms A and B).

TABLE 1 Basic rules for determining the type of dynamic model at each rotatable bond. Hybridisation state of atom A sp¹ sp² sp³ Hybridisation sp¹ not rotated unimodal unimodal state of sp² unimodal bimodal bimodal atom B sp³ unimodal bimodal trimodal

In accordance with these specifications, the modal behaviour initially assigned to a wide variety of covalent bonds is set out below.

Examples of covalent bonds generally considered to have fixed internal coordinate geometries (covalent bonds in black are considered to be fixed).

Examples of covalent bonds generally considered to prefer a unimodal distribution (covalent bonds in black are considered prefer a unimodal behaviour).

Examples of covalent bonds generally considered to prefer a bimodal distribution (covalent bonds in black are considered prefer a bimodal behaviour).

Examples of covalent bonds generally considered to prefer a bimodal distribution, that take cis and trans conformers due to electron conjugation (covalent bonds in black are considered prefer a cis/trans behaviour).

Examples of covalent bonds generally considered to prefer a trimodal distribution (covalent bonds in black are considered prefer a trimodal behaviour).

The initial values of the mean angles for each mode are set to values that are sterically favourable conformations. For example, in a trimodal model, the three mean angles would correspond to the fully staggered state for the bond [15]. Covalent bonds that have an intermediate character between a single and a double bond (due to electron conjugation) are given a bimodal model, where the two mean angles of the two conformations are given cis and trans dihedral geometries. Cyclic chemistries that interconvert between more than one conformation are given bi- or trimodal models as appropriate, where several dihedral angles are simultaneously moved together (see below for some examples).

Examples of cyclic chemistries that can adopt more than one conformation.

During the determination of a dynamic 3D-structure it may become apparent from the best-fit to the experimental data that a rotatable bond that was initially set to a bimodal or trimodal behaviour (according to the table and description above) is actually adopting a lower modal behaviour in the real molecule. In this case, the modal behaviour in the dynamic model file can be updated accordingly.

Where there is previous experimental data available for a rotatable bond's modal behaviour, this can be used to define the modal behaviour. Kinds of experimental data that can be used to define the modal behaviour for a given bond include NMR data (for example the cis/trans forms of a proline amide bond have distinct chemical shifts) or consideration of the range of conformations displayed for that bond (and substituents on atoms A and B) in the Cambridge Structural Database. Where molecular dynamics simulations have been performed, these may be also be used to decide upon the best modal behaviour for the bond.

Having decided upon which rotatable bonds are to be varied in order to find the best fit ensemble to the experimental data, there are two basic kinds of flexibilities defined, which are designated for each bond by a user:

-   -   1) gyrations define unimodal bond flexibilities     -   2) multigyrations define bimodal, trimodal and higher modal bond         flexibilities.

As described below, in a preferred embodiment of the present invention rotatable bonds are designated with a gyration that has a single mean angular value (μ) and a Gaussian spread of angle (σ), and these are optimised by a suitable optimisation algorithm which iteratively generates ensembles of molecular structures and tests each ensemble against real experimental data. Examples of bonds specified in this way are glycosidic linkage bonds in carbohydrates. A rotatable bond designated with a multigyration is assigned multiple geometries that it can adopt (typically related to 2 or 3 low-energy rotamer positions), each of which has an angular value and Gaussian spread of angle that can be optimised, and their relative proportions are specified with probability models (see below). These probabilities can be specified according to the relative intensity of local NOEs/ROEs or by conformational-dependent coupling constants (e.g., hydroxymethyl groups in pyranose rings), but they can also be optimised by the algorithm. An example of a bond typically described with a bimodal multigyration is a peptide C^(α)—C^(O) bond (i.e., the ψ dihedral), which typically jumps between α-helical-like (ψ≈−60°) and β-strand-like (ψ≈120°) geometries. The input data file shown below provides an example of how these modelling considerations can be implemented practically.

variables: var 1 rand 0 360 jump 180 var 2 rand 0 360 jump 180 var 3 fix 18 jump 10.0 start 0.3 var 4 fix −60 jump 0.0 start 0.0 var 5 fix 60 jump 0.0 start 0.0 var 6 fix 15 jump 0.0 start 0.0 var 7 fix −120 jump 0.0 start 0.0 var 8 fix 120 jump 0.0 start 0.0 var 9 fix 0 jump 0.0 start 0.0 var 10 fix 30 jump 0.0 start 0.0 endsection probabilities: mode 1 2 0.5 0.0 mode 2 3 0.33 0.66 0.0 mode 3 4 0.33 0.1 endsection dynamics: gyrate 41 1 3 gyrate 42 2 3 multigyrate 48 1 4 6 5 6 multigyrate 35 2 7 10 8 10 9 10 multigyrate 55 3 7 10 8 10 9 10 endsection

In the variables section of this file, variables are defined using the var command, which each define either a mean value or a Gaussian spread for a rotatable bond's dihedral angle. Following the var command is a number representing the variable number (used to identify the variable later). The next option determines the initial starting value of the variable. For example, “rand 0 3 60” indicates that the initial configuration will be a random value between 0° and 360°, while “fix 18” indicates that the variable starts at 18°. The “jump” option specifies the initial value used for applying random changes to each variable in the optimisation. Large values (˜180) are typically used for variables that will be used as angular degrees of freedom (ensuring that they sample their space effectively), while smaller values (˜10) are used for variables that will be applied as dynamic spreads, which typically have final values up to 25° (see Examples 1, 2 and 3 below). Finally, the “start” option specifies the point at which optimisation will start. Using a value of 0.0 here indicates that optimisation will begin immediately, while a value of 0.5 would start optimisation half-way through the optimisation iterations.

The probabilities section is used to define bimodal and trimodal distributions. After the mode, command is the probability number (used to refer to it) and then a number, which is either 2 for a bimodal distribution, 3 for a trimodal distribution or 4 for a ‘symmetric’ trimodal distribution (where two of the probabilities are equal, see below). The next two or three numbers represent the cumulative probability, at which the different modes will be selected. The final number is a value that allows the probability to be optimised iteratively (a value of 0.0 indicates that the probability model should not change during optimisation). For example, in the above “mode 1 2 0.5” defines a bimodal model, where each conformation has a probability of 0.5 (0.5). The second mode 2 command above specifies a trimodal distribution (e.g., applied to a methyl-group). Both are set not to be optimised. The last mode 3 4 0.33 0.1 command specifies a trimodal distribution with only one degree of freedom, a single probability, p₁. (i.e. a symmetric trimodal model); the other two probabilities are exactly the same, i.e., p₂=p₃=½(1-p₁). In this case p₁ has a floating probability, specified by the last column in this command being 0.1, which is a suitable iteration jump size.

In the dynamics section of this file, the relationship between the defined variables and the molecular dihedral bond angles is specified. A line beginning with gyrate specifies a unimodal probability distribution model, with the three attendant numbers specifying:

-   -   1) the exact dihedral angle in the molecular structure     -   2) the variable to use for the mean value for the dihedral angle         (from the variables section) and     -   3) the variable to use for the Gaussian spread of the dihedral         angle.

For example, in the case above the line gyrate 41 1 3, 41 specifies a dihedral angle (41 is the value for a particular bond used in the internal coordinates table, see Appendices A, B and C associated with Examples 1, 2 and 3 respectively for example internal coordinate files), 1 specifies that var 1 should be used for the mean value and 3 specifies that var 3 should be used for the Gaussian spread.

A line beginning with multigyrate specifies a bimodal or trimodal angular model. In the line multigyrate 48 1 4 6 5 6, for example, the first number (48) specifies the molecular dihedral angle from the internal coordinates table to vary, the second number the probability model to use (1, from the probabilities section), and the subsequent numbers are the appropriate pairs of mean and Gaussian spreads (var 4 & 6 and var 5 & 6) for each of the modes. Probability models 2, 3 and 4 require 2, 3 and 2 pairs of variables respectively.

It should be noted that variables and probability models can be used repeatedly in several gyrate or multigyrate commands, allowing significant flexibility in the way that the dynamic model can be specified. For example, this allows certain rotatable bonds to be coupled (e.g., identical environments within a polymer) or allows multiple bonds to be moved in concert between major conformational states (e.g., cyclohexane ring). The general principles explained above are employed in Examples 1, 2 and 3 below.

Having defined the solvent masks, the van der Waals mask and the dynamic model it is now possible to use the optimisation algorithm to find the values for each of the, for example 10, unknown variables that give the best fit to the experimental data. This may be achieved using a process of repeated rounds of structure calculations. FIG. 4 shows a flowchart that is representative of a preferred embodiment of an overall ensemble generation and optimisation process.

During a round of structure calculations, the optimisation process may be run many times (e.g. around 40 times) to produce many optimised dynamic structures. Each individual run may have the same number of iterative optimisation steps (e.g. around 10,000, for the number of degrees of freedom typically found in a small dynamic molecule) and may employ the same number of structures in the dynamic ensemble (e.g. around 100). The number of optimisation steps and structures in the dynamic ensemble may be kept constant between successive rounds of structure calculations, allowing the results from different rounds to be directly compared, or alternatively the number of optimisation steps and/or the number of structures in the dynamic ensemble may be varied between one or more successive rounds of structure calculations.

In a preferred embodiment, experimental datasets can be progressively added to successive rounds of structure calculations. This may represent a practical limitation because in every dataset file there may be a variety of human and experimental sources of error in the initial restraint list. These sources of error may, for example, include:

-   -   1) mis-assignment of structural restraints;     -   2) incorrect application of scaling factors in determining         structural-restraint intensities;     -   3) incorrect calculation of restraint errors; and/or     -   4) spectral artefacts.

In order to find and correct these mistakes, repeated rounds of structure calculations can be performed, in a manner similar to the determination of protein 3D-static structures by NMR [16]. By initially using a subset of the total dataset that has extremely high confidence of having few mistakes (typically 60-70% of the structural restraints 2D-NOESY and T-ROESY datasets), the few structural restraints that have high χ² _(restraint) scores (i.e. χ² _(restraint)>>10) after a round of structure calculations can be easily identified as outliers. These outliers are fully reanalysed as described above, which is usually successful in determining the source of the inconsistencies and resolving them. In order to check that they have been resolved, another round of structure calculations may be performed with the revised measurements and scaling factors. Once a reasonable subset of the real experimental data (structural restraints) has been found to be consistent with the predicted experimental data, more structural restraints from the real experimental dataset can be included.

This process may be repeated until all the structural restraints in the real experimental dataset can be simultaneously satisfied. Use of a flag field in the structural restraint lists, described above, can be used to rapidly include or omit individual structural restraints in subsequent rounds of calculations. Having completed one real experimental dataset file, another real experimental dataset is included and further rounds of calculations performed, progressively correcting erroneous structural restraints in the new dataset as before, while also correcting erroneous structural restraints in the previous datasets that are now found to be in conflict with the new data.

It will be appreciated from the foregoing discussion that a sufficient number of correctly-measured structural restraints are required in the first instance to achieve rough convergence of the optimised dynamic structures in a round of structure calculation, and, moreover, before erroneous structural restraints inconsistent with that structure can be identified. The dynamic structure has been satisfactorily determined when the inclusion of more structural restraints or whole real experimental datasets of structural restraints results in no change in the final values for the dynamic variables or probabilities in the optimised dynamic structure.

It is preferred that the progress made in solving the dynamic structure is monitored by performing statistics on at least one run, and preferably more, for example, every round of structure calculations. Every run of the optimisation algorithm generates an optimised dynamic structure, which has associated with it the best-fit values for each of the variables and probabilities, the χ² _(total) value for the dynamic ensemble, the χ² _(restraint) value for every structural restraint used in the optimisation and a χ² value for the van der Waals contribution. Using the best runs in the round of calculations (i.e., those with lowest χ² _(total) values), mean values and standard deviations for each of these parameters is calculated; by way of example only, the best 10 runs out of 40 may be used. Mean values and the standard deviations for the χ² _(dataset) values for each dataset file are preferably calculated. These data can be reported in a primary statistics table, which may take the following appearance:

Ranked run no. Mean StDev 22 27 24 10 12 11 5 15 9 26 Datasets 15N-NOE 108.3 4.3 98.6 103.2 106.8 110.5 111.0 112.5 107.5 112.1 108.2 112.4 2D-NOESY 29.6 1.6 31.1 28.6 28.2 29.1 27.3 28.8 33.2 28.9 30.9 29.6 JCOUP 2.6 0.9 2.2 2.7 2.2 2.3 1.6 2.9 3.5 4.4 3.6 1.1 ORDER 2.2 1.5 2.0 2.2 1.5 1.1 2.5 0.2 2.0 0.4 4.5 5.3 VDW 1.3 0.9 2.5 1.9 2.6 0.5 1.7 1.7 0.2 1.0 0.5 0.3 TotChi 143.9 3.8 136.5 138.6 141.2 143.5 144.1 146.0 146.5 146.7 147.6 148.7 Variables var 1 −83.4 8.9 −95.2 −74.3 −88.5 −76.4 −92.8 −96.2 −75.7 −73.2 −74.8 −87.1 var 2 −119.3 5.2 −115.3 −122.9 −112.0 −123.6 −114.5 −121.6 −124.7 −112.1 −119.8 −126.8 var 3 20.9 5.5 18.8 24.4 11.5 25.1 16.3 23.2 25.9 12.4 27.5 23.9 Probabilities p1(1) 0.33 0.0 0.33 0.31 0.33 0.33 0.34 0.33 0.32 0.33 0.33 0.35 p2(1) 0.66 0.0 0.66 0.66 0.66 0.68 0.66 0.65 0.66 0.67 0.64 0.66

In such primary statistics tables, the data from the runs with the best χ² _(total) values are shown (in this case the runs were ranked in terms χ² _(total) and the best 10 runs were selected). The TotChi line gives the χ² _(total) value for each run, as well as the mean value and standard deviation (StDev) for these χ² _(total) values. Above this line, the mean χ² _(total) and its standard deviation are given for each individual dataset file (designated, in this case, 2D-NOESY, JCOUP, ORDER, 15N-NOESY-HSQC that were used in this round of calculations. The mean χ² _(total) and standard deviation values are also given for the van der Waals (VDW) term in each run. Following the TotChi line are the results for the variables specified in the dynamic model file, and then the probabilities.

In a further preferred embodiment of the present invention, in order to determine if any one dataset file is unduly biasing the emerging dynamic structure, a secondary statistics table may also be produced that reports the χ² _(dataset)/restraint for each dataset (Chi/Res) from the number of structural restraints in each dataset file (Restraints) and the total χ² _(dataset) value for the dataset (Tot chi):

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 107 142.3 1.3 0 0 2D-NOESY 82 107.9 1.3 0 0 JCOUP 3 2.6 0.9 0 0 15N-NOESY-HSQC 19 29.6 1.6 0 0 ORDER 3 2.2 0.7 0 0

When no one dataset is unduly biasing the emerging dynamic structure, all χ² _(dataset)/restraint values are ˜1 and are comparable to each other. In the example above, it can be seen that this is indeed the case, although the 15N-NOESY-HSQC dataset might be biasing the structure a little (χ² _(dataset)/restraint=1.6). While the errors for order parameters (ORDER) and scalar coupling (JCOUP) kinds of data can be determined experimentally, the errors for NOESY and T-ROESY datasets depend upon the imprecisely known value m. Suitable values for m based upon experience have been given for the most common kinds of NOESY and T-ROESY experiments (see below), and these can be taken as a guide for other NOESY and T-ROESY experiments. To determine the value of m for other experiments more precisely, different m values can be tried until a χ² _(dataset)/restraint value of ˜1 is achieved, this may be termed balancing. To avoid the process of balancing becoming too subjective, m values comparable to those given below should be used (i.e., between 0.1 and 0.8) and balancing should not be attempted until the base dataset has been determined for the dataset being balanced.

In a similar process to balancing, the most suitable value for τ_(c) can be found if it has not been precisely determined experimentally. An initial estimated value for τ_(c) can be used to allow structure calculations to be preformed and sufficient structural restraints to be used in the optimisation algorithm to produce loosely converging structures. At this point, several rounds of structure calculations that only differ in the value of τ_(c) can be performed, and the value of τ_(c) that gives the lowest mean χ² _(total) value is taken to be the best value for τ_(c) (as described above).

Having determined an initial dynamic 3D-solution structure of a molecule which best fits real experimental data, in a still further preferred embodiment of the present invention the initial best 3D-solution structure is refined by a more extensive round of structure calculations to find the best possible fit to all available experimental data. This structure-refinement round may use some or all of the same real experimental datasets as were used in the previous rounds of structure calculations but, for example the ensemble size may be increased (e.g. to 250 structures), the number of iterative steps may be increased (e.g. to 15000) and/or more runs may be performed (e.g. 100). In addition or alternatively, the dynamic model file can be changed to set the molecule's starting point to be in the best conformation determined in the previous round of structure calculations (i.e., all variables starting in a random conformation are initially fixed to the best value previously determined), and/or only small jump sizes in dynamic parameters are permitted. This allows the known χ² _(total) minimum to be locally searched until the best possible values of the experimental variables and probabilities are determined. Statistics may be performed on this refinement round, preferably in a similar manner to the statistics performed previously in the original dynamic structure calculation rounds which provided the initial ensemble or dynamic structure which best fit all of the real experimental data. Using the best runs from this refinement round, the mean optimised dynamic structure and mean optimised dynamic ensemble may be calculated (e.g. taking the mean values for the variables and probabilities from, for example the best 20 runs of the 100).

Referring now to FIG. 5, there are illustrated a plurality of components which cooperate to provide an implementation of the invention. A user interface component 1 provides an interface between a user and the programmed computer. The user interface component 1 communicates with a plurality of modules so as to process received data and output processed data. For example, a component 2 represents a flexible molecule which is processed by the embodiment of the invention. The flexible molecule represented by the flexible molecule component 2 is received by the user interface 1. Prediction and experimental calculation component 3 predicts experimental data values in the manner described above and uses those predicted values so as to update data associated with a flexible molecule component 2. The prediction and experimental calculation component 3 communicates with a molecular property averager component 4 arranged to produce averages of molecular properties from ensembles of structures. The prediction and experimental calculation component 3 further communicates with an iteration thread 5 configured to perform a plurality of iterations which affect the flexible molecule represented by the flexible molecule component 2. A data storage component 6 stores data required by the system and communicates with a plurality of the system components. A dynamic confirmation generator component 7 compares predictions of experimental data against real experimental data.

The flexible molecule represented by the flexible molecule component 2 is defined in terms of bonds, angles and torsional angles, rather than using Cartesian coordinates. Representation of the flexible molecule is achieved by using a plurality of classes shown in FIG. 6. A molecule class 8 acts as a super class for a flexible molecule class 9. The flexible molecule class 9 has an association with a topology class 10 which in turn has associations with an atom class 11 and a bond class 12. The atom class 11 and the bond class 12 respectively represent atoms and bonds included within molecules.

The data storage component 6 of FIG. 5 is shown in further detail in FIG. 7. A data storage class 13 has an association with a data file class 14 representing a data file. The data storage class 13 also has an association with an experimental data storage class 15 storing experimental data and a physical parameters class 16 storing physical parameters of the molecule of interest. A molecule property storage class 17 also interfaces with the data storage class 13 and stores data indicative of the molecular properties.

The experimental data storage class 15 interfaces with the data storage class in order to make predictions of experimental data chosen by the user and to report the χ² measure for the agreement between predicted and real experimental measurements. The molecular-property-averger component 4 calculates statistics during generation of the dynamic molecular ensemble from the dynamic degrees of freedom that can be used to make predictions of experimental data. This is implemented as multiple instances of a polymorphic class structure that define each type of experimental data. Thus new types of experimental data can be readily added. This is illustrated in FIG. 5.

Referring to FIG. 8, it can be seen that the data_file class 14 has a plurality of subclasses representing different types of experimental data. More specifically, a relaxation_data class 18, an rdc_data class 19, a jcoup_data class 20, a hetnoe_data class 21, a hbond_data class 22, a dihedrals_data class 23 and vdw_data class 24 are all subclasses of the data_file class 14. It can be seen that the data_file class 14 exposes two parameters, an identity parameter identifying the file and a data type parameter being an integer value indicating the type of data. A number of methods are also exposed by the data_file class 14. Specifically, a read data method is arranged to read data from a data file, serialise and unserialise methods are respectfully arranged to serialise the contents of a class or unserialise its content, while a calculate chi-square method is arranged to perform a χ²-calculation. A return data type method returns the data type of the data file represented by the data_file class 14 while an output violations method outputs any violations which may have occurred to the class.

It can be seen that the relaxation_data class 18 has a noe_data class 25, a roe_data class 26 and a troe_data class 27 representing subtypes of relaxation data represented by the relaxation_data class 18.

The class structure described with reference to FIG. 8 allows a variety of different types of experimental data to be represented within a common structure. A plurality of different types of experimental data can be used together to produce a single dynamic model. This was described in further detail above.

It will be appreciated that the class structure described with reference to FIG. 8 provides considerable flexibility and allows any kind of dynamical data that can be related to a physical model to be used within the method described above. For example, NMR relaxation data, fluorescence resonance energy transfer (FRET) data, analytical ultracenrifugation (AUC) data and small-angle X-ray scattering (SAXS) data can all be used.

Where NMR data is employed in the optimisation the molecule under investigation will typically contain both carbon and hydrogen atoms (often referred to as organic molecules) and have one or more covalent bonds that are rotatable (i.e., do not have a fixed geometry). While a pure (>95% single molecular species) molecule may be studied, a mixture of related molecules (i.e., variants with a few atoms being different) or substantially different molecules (for example, in the presence of impurities) can also be used, provided that the experimental observable(s) being measured can be sufficiently resolved or deconvoluted. Molecules can also be analysed in the presence of receptor molecules (such as proteins or nucleic acids), if NMR data can be recorded.

In accordance with standard practice, NMR samples may be prepared by dissolving the molecule of interest in a solvent, typically water (H₂O, D₂O and mixtures thereof) for molecules of biological interest, but organic solvents can also be used where appropriate. Samples are typically made at solute concentrations of 1-100 mM, at approximately neutral pH with up to 300 mM salt (e.g., sodium chloride, phosphate buffer), but are not restricted to these ranges of conditions. Samples typically contain an internal reference compound (e.g., DSS, dimethyl-2-silapentane-5-sulphonate) and an inorganic antibacterial (e.g., sodium azide), but neither of these conditions are mandatory. One or more samples of the molecule of interest with slightly different conditions (e.g., 10% D₂O/90% H₂O v/v, 100% D₂O, presence of alignment media) may be prepared as desired. Molecules have no requirement to be isotopically-enriched (e.g., with ¹⁵N, ¹³C, ¹⁹F or ³¹P) or depleted (e.g., replacement of natural-abundance ¹³C with ¹²C, ¹⁵N with ¹⁴N or ¹H with ²H), but additional experiments can be performed and the data used in the optimisation should the molecule be so enriched or depleted. The NMR samples are used to record NMR datasets using standard pulse-sequences available on any modern NMR spectrometer.

NMR datasets may be recorded on molecular sample(s), prepared as described above, to allow ¹H, ¹³C and/or ¹⁵N nuclei (and any other NMR-active nuclei present) to be assigned (i.e., their NMR chemical shifts determined) and proton-proton homonuclear scalar-coupling constants to be measured. NMR spectra can be recorded at any temperature, provided that the molecule remains in solution. While spectra are typically recorded at a proton-resonance frequency of 600 MHz, higher or lower field-strengths can also be used, assuming suitable spectral resolution can be achieved. These assignment experiments [17, 18] typically comprise:

-   -   1) [¹H]-1D     -   2) [¹H, ¹H]-DQF-COSY     -   3) [¹H, ¹H]-TOCSY     -   4) [¹H, ¹³C]-HSQC     -   5) [¹H, ¹³C]     -   6) [¹³C]-1D spectra     -   7) [¹³C]-filtered [¹H]-1D spectra     -   8) [¹H, ¹⁵N]-HSQC     -   9) [¹⁵N]-1D spectra     -   10) [¹⁵N]-filtered [¹H]-1D spectra.

NMR experimental datasets may then be recorded, which allow for the measurement of parameters that are quantitatively indicative of molecular 3D-structural and dynamical information. The experiments typically performed to achieve this include, but are not limited to:

-   -   1) Nuclear Overhauser enhancements (NOEs) and rotating-frame         NOEs (ROEs). NOE and ROE data are typically measured using         experiments such as [¹H, ¹H]-NOESY, [¹H, ¹⁵N]-NOESY-HSQC, [¹H,         ¹³C]-NOESY-HSQC, [¹H, ¹H]-T-ROESY and [¹H, ¹⁵N]-T-ROESY-HSQC         [19, 20]. In the particular case where water is the solvent, the         solvent signal is usually suppressed using presaturation or a         dedicated pulse-sequence, e.g., one containing the WATERGATE         filter [21].     -   2) Conformation-dependent scalar-couplings.         Conformation-dependent scalar couplings (e.g., ³J) are typically         measured using experiments such as [¹H]-1D spectra, quantitative         E-COSY [22], HNHA [23] and J-modulated ¹⁵N-HSQC experiments         [24].     -   3) Residual dipolar couplings (RDCs), which are typically         measured from [¹H]-1D spectra and experiments such as [¹H,         ¹³C]-HSQC and [¹H, ¹⁵N]-HSQC where broadband heteronuclear         decoupling during acquisition has been disabled [13]. In the         particular case where the molecule is ¹³C and/or         ¹⁵N-isotopically enriched, standard experiments such as those         typically performed on proteins can also be used to measure RDCs         and conformation-dependent scalar couplings (e.g., ³J_(HC)).     -   4) T₁- and T₂-relaxation data and heteronuclear (e.g., ¹H—¹³C or         ¹H—¹⁵N)NOEs [25], which are measured using pulse-sequences that         have been derived previously [6].     -   5) Chemical shift anisotropy, paramagnetic-induced shifts,         hydrogen-bonds (identified by determination of e.g., exchange         rates, proton-carbonyl scalar-couplings, isotope effects or         exchangeable proton temperature coefficients) and salt-bridges         (identified by e.g., pH or NaCl titrations).

As mentioned above, the experimental datasets can be recorded at any NMR field-strength, at any temperature in which the molecule is still soluble and on samples of different compositions. All datasets should be recorded with a sufficient number of datapoints in the acquisition dimension to allow spectral features of interest be resolved (e.g., proton multiplet structure). In the case of NOESY and T-ROESY [26] spectra, the spectrum is preferably recorded with suitable parameters such that proton multiplet components are not resolved in the indirect proton dimension, since this significantly complicates the determination of scaling factors (see below). Spectra are also typically recorded with high signal-to-noise ratios to minimise errors on peak-height and chemical-shift (peak-centre) measurements.

In NOESY, ROESY and T-ROESY NMR datasets, the structural and dynamical information is encoded within the intensities of peaks (both diagonal and cross-peaks) of the respective spectra and therefore these peak intensities must be accurately determined (often achieved by measuring the maximum peak-heights). However, with the exception of those protons in the molecule that have no homonuclear scalar couplings (e.g, an aldehyde proton), each peak from a proton is multiply split into a resonance multiplet [27] in the acquisition dimension, according to the number and magnitudes of the scalar couplings associated with the proton, the NMR field-strength, and the difference in chemical shift between the proton and those protons scalar-coupled to it.

Since the true peak-height for one mole abundance of protons is required for input into the algorithm (described below with reference to FIGS. 9, 10 and 11), these splittings must be compensated for to allow the correct equivalent peak-height value for one mole abundance of protons to be calculated. This is achieved by the use of scaling factors, ƒ. In brief, the scaling factor for each resonance in a resonance multiplet must be determined, which is a conversion factor that allows the observed height of a resonance in a resonance multiplet to be converted to the value for one mole abundance of protons. The set of scaling factors for the resonance multiplet of a particular proton is termed the scaling factor set, ƒ_(i)={i_(i), . . . , i_(n)}. It is therefore necessary to know the scaling factor set for the proton in the acquisition dimension of the observed NOE (or ROE) to determine the equivalent one mole abundance height of the observed NOE. The determination of scaling factor sets, and their use in calculating one mole abundance true peak heights, is detailed below.

Proton resonance multiplets arise from scalar-couplings between adjacent protons. In the first-order case, each scalar-coupling bifurcates the proton lineshape, and therefore for c scalar-couplings to a proton, the proton will have 2^(c) multiplet components. This first-order case occurs when the so-called weak-coupling limit is satisfied, which is when the difference in frequency between two nuclei I and S(ΔN_(IS)) is considerably greater than the scalar-coupling (J_(IS)) between them (a working definition would be that the frequency difference is ten times the scalar-coupling), described by equation (15).

ΔN _(IS) =|N _(I) −N _(S) |>>J _(IS)  (15)

wherein N_(I) is the measured resonance frequency for nucleus I, N_(S) is the measured resonance frequency for nucleus S, (ΔN_(IS)) is the difference in frequency between nuclei I and S, and (J_(IS)) is the scalar-coupling between nuclei I and S.

In the case of weakly-coupled protons and when the value of each homonuclear coupling-constant is known (described above), proton scaling factors can be explicitly and easily calculated (see below). However, when the weak coupling limit is not satisfied, the nuclei are said to be strongly-coupled, and distortions to resonance multiplet lineshapes occur that are not expected at first-order. These distortions prevent the easy calculation of scaling factors (see below) and therefore the scaling-factor sets for protons that are weakly- and strongly-coupled are determined with different methodologies. Since proton homonuclear coupling constants are typically less than 15 Hz (J_(IS)), it can be easily ascertained with equation (1) whether a proton is weakly coupled to the other protons that it is scalar-coupled to at a particular proton resonance frequency (Hz), once the protons' chemical shifts have been determined through the standard processes of assigning the protons in the molecule (described above).

When a proton satisfies the weak-coupling limit for all protons it is scalar-coupled to, the proton's scaling-factor set may be determined according to the following methodology. In the most simple case, all the multiplet components are resolved from each other, i.e., a proton with c scalar-couplings will have 2^(c) multiplet components uniquely visible in the spectrum as 2^(c) resonances in the resonance multiplet. In this case, all the resonances will theoretically have the same height as each other, and the scaling factor for each resonance in this case is therefore also 2^(C), as shown in FIG. 9. The scaling-factor sets for each peak produced by the presence of 0, 1, 2 or 3 homonuclear coupling constants are given explicitly in FIG. 9. Such scaling-factor sets are termed simple scaling-factor sets.

In more complex cases for protons obeying the weak-coupling limit, multiplet components overlap with each other to some degree, meaning that fewer distinct resonances (than the number of multiplet components, 2^(c)) are observed in the spectrum. The extent and nature of the overlap depends upon both number and magnitude of the scalar-couplings to the proton and the intrinsic proton resonance linewidth at half-height in the spectrum (λ, which is itself dependent upon the temperature, the solvent conditions and the molecule's correlation time). Since λ is a property of a particular spectrum, it is therefore clear that scaling-factor sets must be determined for each spectrum that will be quantified. The intrinsic proton resonance linewidth at half-height (λ) in a spectrum is measured by taking the mean of the linewidth at half-height from several resonances that are resolved from overlap with other resonances (e.g., an aldehyde proton, which has no homonuclear scalar couplings). Multiplet components will overlap (i.e., will not be individually resolved) when the difference in resonance frequency (Δv) between the components is less than or equal to the value of λ (i.e., Δv≦λ) and will manifest in the spectrum as a single resonance, which is higher than that expected for an individual multiplet component. Moreover, unless the multiplet components overlap exactly (i.e., Δv=0) the resonance will be broader than the non-overlapped multiplet components in the spectrum.

The degree of overlap of a proton's multiplet components depends upon the values of the homonuclear scaling-couplings to that proton. Where the coupling constants all coincidentally have the same value (J), and that value is larger than the intrinsic proton resonance linewidth at half-height (i.e., J>λ), the multiplet components overlap perfectly (i.e., Δv=0) and give ideal scaling-factor sets. The appearance of the proton lineshapes, and their associated scaling-factor sets, are shown in FIG. 10, for the cases of 1, 2, 3 and 4 identical homonuclear scaling coupling constants being present.

In the rather more common case where the coupling constants do not all have the same value, the multiplet components do not overlap perfectly (i.e., Δv≠0) and non-ideal lineshapes are observed. Such multiplet components may be analysed using a method according to the fourth aspect of the present invention as defined above, specific embodiments of which are now described in detail to demonstrate the application of that aspect of the present invention.

These non-ideal line-shapes will generally have an appearance similar to one of the resonance-multiplet patterns shown in FIGS. 9 and 10. In this case, the scaling factor set from the non-ideal proton is initially taken from the lineshape in FIG. 9 or 10, which is most similar to that observed in the spectrum. For each resonance in this multiplet that is broadened by non-perfect overlap of multiplet components, the value Δv between the overlapping components is explicitly calculated from the known values of the homonuclear coupling constants. For example, if a proton has a single scalar-coupling of 3 Hz (Δv=3 Hz) to a second proton and the spectrum's intrinsic line-width at half-height is 6 Hz (λ=6 Hz), the two multiplet components will not overlap perfectly with each other, and a single broad resonance will be observed in the spectrum, which has a height lower than that required for one mole abundance of protons, yet taller than half the value of one mole abundance protons. Since a single resonance is observed, this proton's multiplet pattern is most like the case shown in FIG. 9 (a proton with no scalar coupling) and the scaling factor set is initially taken to be ƒ={1}. However, the height of this single broadened resonance must be further scaled by the appropriate broadening adjustment (b) to determine the height that would have been observed for the overlapped resonance if the two components had overlapped perfectly. This broadening adjustment can be shown (see FIG. 11 for a schematic involving one scalar coupling, J) to be modelled suitably by equation (16).

$\begin{matrix} {b = {{\frac{\lambda}{\lambda - \left( {\Delta \; {v/2}} \right)}\mspace{14mu} {for}\mspace{14mu} \Delta \; v} \leq \lambda}} & (16) \end{matrix}$

Therefore, in the case of the proton described above with a single scalar-coupling constant of 3 Hz (Δv=3 Hz) in a spectrum with an intrinsic line-width at half-height of 6 Hz (λ=6 Hz), the broadened resonance with initial scaling-factor set ƒ={1} is converted via broadening adjustment b=6/(6−(3/2))=1.3 to be ƒ={1.3}. This set of combined scaling factors is the correct scaling factor required to convert this resonance's experimentally-measured height into an equivalent height for one mole abundance protons. Each broadened resonance within a resonance multiplet may be similarly treated, to determine a set of combined scaling factors for a non-ideal weakly-coupled proton.

As a second, particularly common example, consider a proton with two scalar-couplings of 8 Hz and 10 Hz, in a spectrum with intrinsic line-width at half-height of 6 Hz (λ=6 Hz). The line-shape of this proton is most like that of a proton with two identical scaling coupling constants (FIG. 10), in which the two central multiplet components overlap and make a resonance approximately twice as high as the two outer resonances. The resonances are therefore given an initial scaling factor set of ƒ={4, 2, 4}. The separations between the multiplet components are clearly 8 Hz (first and second components, Δv_(1,2)=8 Hz), 2 Hz (second and third components, Δv_(2,3)=2 Hz) and 8 Hz (third and fourth components, Δv_(3,4)=8 Hz). Since the values of Δv_(1,2) and Δv_(3,4) are less than λ, the outer multiplet components do not overlap with any other multiplet components and therefore no broadening adjustment is required. However, for the two interior multiplet components (which non-perfectly overlap to give a single broad resonance, since Δv_(2,3)<λ) a broadening adjustment is applied. The combined scaling factor, ƒ, for the central resonance in the multiplet is given by the initial value, i.e., 2×b, where b=5/(5−(2/2))=1.25 (since Δv_(2,3)=2, λ=5), which is 2×1.25=2.5. Therefore, the scaling factor set for this proton's resonance multiplet is ƒ_(i)={4, 2.5, 4}. By using these formulae and rules, it is possible to explicitly calculate the combined-scaling-factor sets for protons with different numbers and magnitudes of scalar-couplings in any given particular spectrum, as long as the weak-coupling rule applies. A variety of different examples are given in the worked example of a hyaluronan hexasaccharide (see worked examples below). More general rules for calculating multiplet patterns beyond the simple cases exhibited here have been published [27].

It can be readily seen from broadening adjustment equation (16) that when the value of Δv is equal to λ, then b=2 (i.e., the two multiplet components only just overlap and create a resonance appearing in the spectrum as a broad plateau at the same height as the individual multiplet components). It can also be seen that when the two multiplet components overlap perfectly (i.e., Δv=0), then b=1, which is equivalent to the numeric sum of the scaling factors of the multiplet component individually, and equivalent to the case of ideal scaling factors sets, where no broadening is present.

When a proton is strongly-coupled to other protons, i.e., it does not satisfy equation (15), the proton's scaling-factor set may be determined according to the following methodology. First a spectral-peak resulting from that proton (i.e., the chemical shift in the acquisition dimension corresponding to that proton) is sought (with strong signal intensity) that does not overlap any other peaks. In the selected peak, therefore, all the resonances in the multiplet can be clearly observed without being obscured by overlap from other peaks in the spectrum. The line-widths at half-height of the resonances in the multiplet are then measured directly from the spectrum, to determine whether any are particularly broader than any other in the resonance multiplet. When the resonances are indeed all approximately as broad as each other (which may be considered to be when the widest resonance is less than twice as wide as the narrowest resonance) the proton's scaling factor set can be determined as follows. The height of each resonance is measured directly from the spectrum (h_(i)), and the scaling factor for each resonance (ƒ_(i)) is determined using equation (17).

$\begin{matrix} {f_{i} = \frac{\sum\limits_{i = 1}^{i = n}\; h_{i}}{h_{i}}} & (17) \end{matrix}$

In this manner, a scaling-factor set can be determined for each strongly-coupled proton, provided a clearly-resolved peak can be identified in the spectrum. It is noted that equation (17) gives reasonably accurate results only when each resonance in the multiplet has approximately the same line-width at half-height and when the heights of all resonances in the resonance multiplets can be measured accurately. When the resonances do not have approximately the same line-width at half-height, volumes of each resonance (v_(i)) may be used instead of heights in equation (17), provided the volumes can be measured with sufficient accuracy.

The different NMR datasets containing information on the structure and dynamics of the molecule are analysed and datapoints within each spectrum are converted in particular ways, depending upon the kind of data contained in the spectrum. These procedures are required to convert the data into a form suitable for use by the dynamic structure calculation algorithm (described above). In addition to the measurement of each structural-restraint's value, the measurement's standard error must also be determined so that the algorithm can calculate how good a fit the dynamic model is to the experimental data.

Structural restraints from NOESY, ROESY and T-ROESY are derived by measuring both diagonal and cross-peak heights from the spectra. Having determined the scaling factor sets for the resonances in a proton's resonance multiplet (see above), the true peak height (H) for one mole abundance of protons from each resonance can be calculated as follows. The resonance height (h_(i)) of each resonance in the resonance multiplet is measured directly from the spectrum and multiplied by the relevant scaling factor ƒ_(i) from the scaling-factor set, giving an individual measure of the true peak height, H_(i), equation (18).

H _(i) =h _(i)×ƒ_(i)  (18)

By measuring several resonance heights in the resonance multiplet and multiplying each by its associated scaling factor, several different values for the true peak-height (H) are therefore calculated. The best value to use for the true peak height is therefore the mean value (<H>) from these repeated measurements, equation (19).

$\begin{matrix} {{\langle H\rangle} = \frac{\sum\limits_{i = 1}^{i = n}\; H_{i}}{n}} & (19) \end{matrix}$

Using formula (19), the true peak-height of every peak (both diagonal and cross-peaks) in the NOESY or ROESY spectrum may be calculated, for direct input into the algorithm. Each true peak-height is associated with a pair of protons, being the NOE or ROE assignment denoting the protons for which the NOE or ROE value should be predicted by the algorithm. Each true peak-height is also given a calculated standard error value (see below). The designation of the two protons experiencing the NOE/ROE effect, with true peak-height value and standard error on the true peak-height value, is termed an NOE or ROE structural restraint. In the case of overlapped NOE or ROE structural restraints (which occur particularly when the protons forming the peak in the spectrum have identical chemical shifts) several pairs of protons are together causing the peak in the spectrum, and the algorithm therefore calculates the combined predicted value for the true peak-height for this group of protons pairs. It is noted that cross-peaks in a homonuclear 2D-NOESY, ROESY or T-ROESY spectrum that are assigned to protons that are scalar-coupled to each other are generally not useful in the generation of accurate structural restraints. This is because the evolution of the scalar coupling(s) during the NOE or ROE mixing time significantly distorts the resonance multiplet lineshape and structure in non-trivial ways, making it intractable to analysis in this manner.

Having determined the mean true peak-height (<H>) of a peak, the estimated error (ε_(exp)) on this measurement must also be calculated. Sources of error in the calculated mean true peak height include the signal-to-noise of the spectrum, intrinsic non-idealities in the lineshape of each resonance due to phase-twists and spectral artefacts and the scaling of the error in each measured resonance height by the scaling factor applied to it. The signal-to-noise of the spectrum (s) is measured directly. Non-idealities in the lineshape of each resonance may be considered to give a uniform systematic error across NOESY, ROESY and T-ROESY spectra that is directly proportional to the height of the measured resonance. The constant of proportionality is termed m and may be considered to be approximately 0.4 (i.e., ˜40% of the measured resonance height) in the case of 2D-NOESY spectra, 0.5 in the case of 2D-T-ROESY spectra, 0.2 in the case of ¹⁵N-T-ROESY-HSQC spectra, and 0.4 in the case of ¹⁵N-NOESY-HSQC spectra. Therefore, according to standard statistical procedures, the error ε(h) in the measurement of each resonance height, h, from the spectrum that results from these two systematic errors is given by equation (20).

ε(h)=√(m ² h ² +s ²)  (20)

In determining the true peak-height, each measured resonance height is multiplied by the appropriate scaling factor (ƒ_(i)). This results in an error ε(H) on each individual measure of the true peak-height (H), which is given by equation (21).

ε(H)_(i)=ƒ_(i)√(m²h_(i) ² +s ²)  (21)

For a resonance multiplet of several resonances, therefore, each estimate of the true peak height (H₁) has an associated estimated standard error of ƒ_(i)√(m²h_(i) ²+s²). Just as a mean value for the true peak-height (<H>) was calculated, the appropriate single value to use for the estimated standard error (ε_(exp)) is given (according to standard statistical procedures) by equation (22).

$\begin{matrix} {ɛ_{\exp} = \sqrt{\frac{1}{n}{\sum\limits_{i = 1}^{i = n}\; {f_{i}^{2}\left( {{m^{2}h_{i}^{2}} + s^{2}} \right)}}}} & (22) \end{matrix}$

A further complication that can occur in the determination of peak-heights in a NOESY or T-ROESY spectrum is that resonances from different peaks can overlap to greater or lesser extents, dependent upon the chemical shifts of the protons forming each peak. Where the difference in Hz between two overlapping resonances (Δv) of equivalent mole ratio (e.g., an overlap of two resonances from different doublets) can be precisely determined (using the known chemical shifts of each proton, and the frequency of each resonance in the resonance multiplet calculated from the scaling-factor sets and scalar-coupling), the above formula for broadening adjustments can be directly applied, resulting in a quantified overlapped NOE or ROE structural restraint (i.e., the true peak-height represents the sum of two or more NOEs/ROEs) for use in the algorithm. Where the overlap is caused by two components of non-equivalent mole ratio (e.g., a doublet resonance at 0.5 mole proton abundance, overlapping with an outer triplet resonance at 0.25 mole proton abundance), the overlap and broadening adjustments may be appropriately weighted to accommodate this non-equivalence.

In the case where a mixture of related molecular species (i.e., variants with a few atoms being different) is present in the NMR sample, some NOEs/ROEs will be from protons present at mole abundance (i.e., those in the parts of the molecule where there are no differences in chemical structures), whereas others will be at a significantly reduced mole abundance (i.e., NOEs between parts of the molecule that vary in chemical structure between the mixture of molecular species). For example, in the case of sugars with a reducing terminus, it is known that the reducing terminal ring exists in solution as a mixture of α- and β-anomers of typical relative abundances (r) 0.4 and 0.6 mole per mole, respectively, whereas the rest of the molecule is identical. NOEs between groups in the rest of the molecule will therefore be present at 1 mole abundance, whereas NOEs to protons in the α- or β-rings will have a reduced intensity. In the case of NOEs from a proton not in the reducing terminal ring to a proton in the α-reducing terminal ring, the intensity will therefore be 40% of what it would have been if the α-form was at 100% abundance. The true peak-height (determined from measured resonance heights from a resonance multiplet and scaled by scaling factors as above) must therefore be additionally multiplied by a factor of 1/r to determine the one mole value. The estimated standard error ε_(exp) on the true peak-height in these cases is now therefore calculated by equation (23).

$\begin{matrix} {ɛ_{\exp} = \sqrt{\frac{1}{n}{\sum\limits_{i = 1}^{i = n}\; \frac{f_{i}^{2}\left( {{m^{2}h_{i}^{2}} + s^{2}} \right)}{r^{2}}}}} & (23) \end{matrix}$

A similar lack of protons behaving at one mole abundance can occur through non-uniform excitation of protons within the molecule due to the NMR pulse-sequence employed. This is especially true in the case of protons close to the water resonance in water samples, in which a WATERGATE excitation profile is used to minimise the signal from H₂O. To overcome this problem, resonance heights from protons in spectra, in which uniform excitation has been achieved (e.g., a 1D spectrum with light presaturation to reduce the water, or a ¹³C-filtered 1D spectrum), may be compared against resonances from spectra with non-uniform excitation (e.g., a 1D spectrum with WATERGATE) and the ratio of resonance heights can be used to provide the suitable resealing factor for one mole abundance in all experiments employing the same excitation profile (e.g., 2D NOESY with WATERGATE). The errors on true peak-heights derived in this way are determined in the same fashion as for mixtures of molecules making non-mole-abundance protons, equation (9), caused by having a mixture of molecules. Clearly, since these excitation profiles introduce another source of error, uniform excitation of proton signals is to be preferred where experimentally possible.

The use of ‘noNOEs’ and ‘noROEs’ structural restraints from each NOESY and ROESY spectrum may be an important part of the analysis of each dataset. In addition to increasing the size of the dataset, the importance of noNOEs and noROEs lies in the restrictions they impose on the relative 3D-space that atoms in the molecule can occupy across the molecular ensemble to still remain consistent with the experimental data. A noNOE (or noROE) is assigned when there is no signal intensity above the noise of the spectrum at the chemical-shift coordinates (where a correlation may have been possible). Such noNOEs may be given a true peak-height of zero and their standard errors set to a third of the value of the intensity measured at the chemical-shift coordinates multiplied by the smallest scaling factor from the acquisition dimension proton's scaling-factor set (i.e. ε_(exp)=(ƒ_(min)×h_(zero))/3, where ƒ_(min) is the smallest scaling factor from the acquisition dimension proton's scaling-factor set and h_(zero) is the intensity measured at the chemical-shift coordinates). As many noNOEs (and noROEs) as possible are assigned within each spectrum.

Another kind of NMR data that reports 3D-molecular structure and dynamics are conformation-dependent scalar-couplings. These are measured and their standard error determined from standard experiments such as those described above. Each scalar-coupling is related to an appropriate Karplus relation [28] for input into the algorithm; appropriate Karplus relations may be taken from published literature or explicitly calculated using quantum-mechanical approaches. In some specific cases, the measured coupling constant(s) can be directly related to a discrete molecular geometry or sets of molecular geometries. In these instances, the distinct bond rotamer states and their relative proportions may be explicitly expressed in the molecular internal coordinates model used by the algorithm. An example of this case is the hydroxylmethyl group of pyranose rings, where the relation of Hasnoot et al. can be used to explicitly calculate the relative proportions of gg and gt conformers [29].

A further kind of NMR data that reports 3D-molecular structure and dynamics are residual dipolar couplings (RDCs). Residual dipolar couplings are measured as the apparent change observed in a scalar-coupling when the molecule is in the presence of weak alignment media (e.g., phage, bicelles, gels) [13]. First, coupling constants (1-, 2- and 3-bond) in the molecule are measured from appropriate spectra recorded in the absence of alignment media, using standard methodologies. These same couplings are then measured in identical spectra recorded in the presence of alignment media, and the difference in Hz between the two measurements is the residual dipolar coupling (RDC). The error associated with determining this RDC may also be calculated, using standard statistical methods (such as that described below for the particular case of RDCs measured from a [¹H, ¹³C]-HSQC spectra).

A particular experiment which can be used to measure RDCs, when the molecule of interest is not isotopically-enriched, is a [¹H, ¹³C]-HSQC spectrum recorded at ¹³C-natural abundance without ¹³C-broadband decoupling during acquisition. This experiment not only allows ¹J_(CH) couplings to be directly measured, but allows sufficient data points in the acquisition dimension to be recorded so that the multiplet components caused by proton couplings are resolved. Each ¹J_(CH) coupling (J) can then be measured several (n) times as the separation in Hz between analogous resonances in each high- and low-field resonance multiplet, giving a mean value (μ_(J)) and standard deviation (σ_(J)) associated with each measurement. The root-mean-square deviation (RMSD) of all ¹J_(CH) couplings within the dataset is then calculated, and this is taken to be the standard error associated with each individual ¹J_(CH) coupling (σ_(j)). Similarly, the mean value (μ_(R)) and standard error (σ_(R)) of each ¹J_(CH) coupling is determined when in the presence of alignment media. The residual dipolar coupling (D) may then be calculated as the difference in Hz between the two mean values (μ_(R)−μ_(J)) and its standard error (σ_(D)) is given by the square root of sum of the squared standard errors (√(σ_(D) ²+σ_(J) ²)).

Compound RDCs (where compound RDCs are defined as the sum of two or more RDCs) for proton-proton RDCs can also be simultaneously measured from such a decoupled [¹H, ¹³C]-HSQC spectrum. These can be measured using the fact that the separation in Hz between the outermost components of each proton multiplet is equal to the sum of all the 2- and 3-bond proton scalar couplings forming that multiplet, when there is no strong-coupling present. Similarly, in the presence of alignment media, this separation is equal to the sum of all the 2- and 3-bond proton scalar-couplings combined with the proton-proton RDCs forming that multiplet. By subtraction of these two values and performing similar statistical analyses to those described above, a compound RDC and its standard error can be measured.

Having employed one or more of the processes described above, structural restraints with quantified errors will have been extracted and appropriately converted from NMR experiments that sample the molecular 3D-structure and dynamic motions of the molecule of interest. While the dynamic structure of a molecule can be determined from a single NMR dataset containing structural and dynamical data (e.g., a 2D-NOESY), significantly greater accuracy may be achieved when two or more real experimental datasets, that have different kinds of data (e.g., NOE data with RDC data), are used because the different kinds of experiment sample molecular motions in qualitatively different ways, i.e., by reporting various different averages of molecular distances and geometries, according to the physical theories that describe them. Where two or more experimental datasets contain the same type of data that was recorded in slightly different ways (e.g., 2D-NOESY and ¹³C-NOESY-HSQC datasets, or multiple 2D NOESY datasets with different NOE mixing times), there is an improvement to the accuracy of the determined structure, but it may not be as substantial. When more than one real experimental dataset is being used, each dataset is kept as a separate list of structural restraints for use by the algorithm as described above.

The methods described above permit the determination of the 3D-structure of dynamic molecules. Such structures are useful because they enable a multiplicity of analytical and computer modelling exercises to be undertaken that can predict experimental observables. The technology has applicability to a wide range of molecules, such as, but not limited to the following examples:

-   -   1) carbohydrate ligands and carbohydrate-mimetics (e.g.,         aminoglycoside antibiotics);     -   2) peptides and artificial peptide mimetics;     -   3) drug molecule molecular flexibilities;     -   4) flexible protein sidechains within an enzyme/receptor active         site or protein-protein interaction site;     -   5) flexible bases within nucleic acid molecules, (e.g, RNA         aptamers); and     -   6) proteins with several conformational states (e.g., integrins)         and intrinsically unfolded proteins.

Any research and development project requiring structural information on flexible molecules will dramatically benefit from dynamic structures generated according to a preferred embodiment of the present invention, particularly those involving ligand-protein interactions. A further potentially important use of the dynamic structures generated according to the present invention is in rational drug design (RDD), i.e., using computers to design molecules that interact with target proteins in specific ways. Since RDD relies upon interaction-energy predictions, it requires detailed and accurate physical data for both drug and protein. Currently, predictions are poor, as seen by the fact that only ˜10% of predicted molecules successfully bind to their receptor. To improve this, data is needed concerning both the enthalpic contribution to binding energy (formation of intermolecular bonds, governed by the molecular shape) and the entropic contribution to binding energy (change in disorder and flexibility on binding). Molecular bonding interactions (enthalpy) can be estimated well, but molecular flexibility (entropy) cannot, and without this flexibility information RDD is fundamentally limited in its predictive capability. Using both the drug molecule's preferred structure (internal enthalpy) and dynamic motions (entropy) determined with our methodology will therefore result in significant improvements in hit identification and lead optimisation via RDD approaches [30]. The methodology allows the dynamic structure of pharmaceutical molecules to be determined, which will significantly aid the discovery of new drugs by rational drug design and chemical mimicry.

Furthermore, the present invention and the dynamic 3D-structures that are produced from it can be used to calculate the deviation of a free solution structure from its bound form and used as an accurate scoring function (see FIG. 12). Dynamic structures therefore provide a significant advance in predictive power for understanding potential ligand-receptor interactions, compared with techniques that only consider enthalpic energy terms (e.g., hydrogen bonds, hydrophobics, etc.) or use molecular dynamics simulations. In particular, this will permit docking to be performed more accurately, with scoring functions that quantitatively fit to experimentally-measured binding constants and interaction energies [32]. Other areas that can benefit from the present invention include:

-   -   1) the generation of biomimetic molecules e.g., the design of         heparin mimetics;     -   2) the analysis of molecular interactions using arrays of         receptor molecules, e.g., in systems biology and proteomics;     -   3) the design of drug-libraries from predictions of likely         reaction routes in combinatorial chemistry; and     -   4) design and construction of molecular machines         (nanotechnology).

The present invention will now be further described with reference to the following non-limiting examples, in which:

FIG. 1. (a/b) shows the dihedral angle α, (a) from the side & (b) looking down the central bond, while (c) shows the Gaussian distribution of a that is used to generate the dynamic ensemble;

FIG. 2. Models for the angiotensin-4 peptide (VAL-TYR-ILE-HIS-PRO-PHE). Left: static structure for angiotensin-4. Middle: ensemble made by applying the Gaussian distribution)G(−57°,20°), as described above, to the φ-angle between TYR and ILE (C[2]-N[3]-Cα[3]-C[3]). Right: ensemble made by applying the distribution) G(−57°,20°) to the φ-angle between TYR and ILE and)G(−20°,20°) to the ψ angle between ILE and HIS (N[3]-Cα[3]-C[3]-N[4]);

FIG. 3. A schematic flowchart representation of a dynamic-structure determination method in accordance with a preferred embodiment of the present invention;

FIG. 4. Flowchart showing the overall process used to determine the 3D-structure of a dynamic molecule in accordance with a preferred embodiment of the present invention;

FIG. 5 is a schematic illustration of components used to implement an embodiment of the present invention;

FIG. 6 is a UML diagram showing classes used to represent a flexible molecule;

FIG. 7 is a UML diagram showing classes used to store data;

FIG. 8 is a UML diagram showing classes used to represent data files;

FIG. 9. Proton-resonance scaling factors for the simple case where all multiplet components are resolved. This occurs when the scalar-couplings (J₁, J₂, . . . ) are large compared to line-widths and they are sufficiently dissimilar;

FIG. 10. Proton-resonance scaling factors for the case where not all multiplet components are resolved, but overlaps are perfect due to chemical similarity. This can happen when the scalar-couplings (J₁, J₂, . . . ) are large compared to line-widths and have the same value, J;

FIG. 11. Calculation of the broadening factor (b) that has to be applied to components of a proton-resonance multiplet that overlap in order to interpret the height of that resonance quantitatively, using a set of combined scaling-factors;

FIG. 12. Use of structure determination in docking studies (see Examples for details below). The co-complex structure shown above is taken from the protein databank (code 2JCQ) [31];

FIG. 13. The repeated disaccharide unit of hyaluronan, which comprises N-acetyl-D-glucosamine (GlcNAc) and D-glucuronic acid (GlcA). These residues are connected by alternating [3]-6 and 131-4 glycosidic linkages (indicated);

FIG. 14. Hyaluronan hexasaccharide (HA₆) exists in aqueous solution as a mixture of α- and β-stereoisomer forms due to the presence of a hemiacetal group in the terminal GlcNAc ring (ring 6). The chemical-bonding difference between these two forms is indicated with an asterix. GlcA=D-glucuronic acid; GlcNAc=N-acetyl-D-glucosamine; numbers refer to ring number designations;

FIG. 15. Two- and three-bond homonuclear scalar coupling constants in GlcNAc (left) and GlcA (right) residues in HA oligosaccharides. The proton names (e.g., HN, H-6proS, H2) and value of the coupling (in Hz) for each coupled pair of protons are indicated. Ring hydrogen atoms have been omitted from the chemical structure for the sake of clarity;

FIG. 16. Conformationally-flexible bonds and chemistries within α-HA₆;

FIG. 17. Relationship of each variable in the dynamic model file to the rotatable bonds in α-HA₆;

FIG. 18. Mean 3D-solution structure of α-HA₆. (Top) stick representation with hydrogen atoms omitted. (Bottom) space-filling representation. Ring 6 is at the left in both views;

FIG. 19. 3D-solution structure of α-HA₆, showing the best ensemble of 250 structures that are collectively consistent with all the experimental data. (Top) Best-fit dynamic ensemble. (Bottom) Best-fit dynamic ensemble overlaid on the central two rings. Ring 6 is at the left in both views;

FIG. 20. Individual structures selected from the dynamic ensemble of 250 structures. These represent possible momentary solution conformations of α-HA₆. Hydrogen atoms have been omitted;

FIG. 21. Chemical structure of lisinopril, showing its ionization state at pH 6.0;

FIG. 22. Lisinopril exists in aqueous solution as a mixture of trans and cis stereoisomer forms due to the presence of the proline amide bond. The difference between these two forms is indicated in black;

FIG. 23. Proton chemical shifts for trans lisinopril in 100% D₂O at pH*6.0, 278K;

FIG. 24. ³J_(HH) coupling constants measured in trans lisinopril;

FIG. 25. Conformationally-flexible bonds and chemistries within lisinopril;

FIG. 26. Relationship of each variable (v) and probability mode (m) in the dynamic model file to the chemical structure of trans lisinopril;

FIG. 27. Mean 3D-solution structure of lisinopril. (Top) Stick representation and (Bottom) space-filling representation;

FIG. 28. Dynamic 3D-solution structure of trans lisinopril, showing 20 random structures from the best ensemble of 250 structures;

FIG. 29. Correspondence of the dynamic solution structure of trans lisinopril (thin blue lines; overlay of 20 random structures from the best ensemble of 250 structures in the best ensemble) to the structure of trans lisinopril when bound to ACE (thick yellow lines) [41]. It is clear that the ensemble of structures for the unbound solution conformation of lisinopril provides a good starting point for predicting a likely enzyme-bound conformation;

FIG. 30. Two views of the 3D dynamic solution structure of trans AngiotensinI, showing 10 structures from the best dynamic ensemble of structures. Each residue is labelled. The two views are rotated approximately 90° relative to each other and only the heavy atoms are shown;

FIG. 31. Two views of the 3D dynamic solution structure of trans AngiotensinI, showing the mean dynamic structure in spacefilling (top) and sticks (bottom) representations. Hydrogen atoms have been omitted from the sticks representation. Both views are in an identical orientation, with Asp1 on the left; and

FIG. 32. Structure of Lisinopril (left), derivative developed in silico designed to remove undesirable degree of freedom by inclusion of briding group (shown in bold) (top right), and next-generation ACE-inhibitor, Benazeprilat (bottom right).

EXAMPLE 1 Hyaluronan Hexasaccharide

Hyaluronan (HA) is a carbohydrate composed of a repeated disaccharide of N-acetyl-D-glucosamine (GlcNAc) and D-glucuronic acid (GlcA) (see FIG. 13). Amidst many other functions, HA provides structural integrity and organisation to vertebrate extracellular matrices. The polysaccharide form of HA, which has thousands of disaccharide repeats, is involved in both physiological (e.g., cervical ripening, tooth development) and disease processes (e.g., endometrial cancer, atherosclerosis). Oligosaccharides of HA, which have only a few disaccharide repeats, have distinct activities under other conditions (e.g., inducing dendritic cell maturation). HA is consequently commercially important in the biotechnology and cosmetics sectors.

Oligosaccharides of hyaluronan are easier to study than the polymer, since they can be purified to a homogenous preparation of defined length and do not form extremely viscous solutions as the polymer does [33]. The hexasaccharide of HA (HA₆, FIG. 14), which comprises only three repeated disaccharides of HA, has been shown to be a length of HA long enough to have the local structural characteristics of the polymer that is still being amenable to structural analysis by NMR [34, 35]. In this worked example, we demonstrate how the dynamic 3D-solution structure of HA₆ was determined from experimental NMR data using the methodology described in this patent.

Chemical Shift Assignment and Measurement of Homonuclear Scalar Coupling Constants

Due to the presence of a ‘reducing terminus’ in HA₆ (i.e., a hemiacetal group), the terminal ring of HA₆ (ring 6) actually exists in solution as an inseparable mixture of α- and β-stereoisomers (FIG. 14); these two forms have near-identical chemical shifts [34]. We have previously assigned all ¹H, ¹⁵N and ¹³C chemical shifts within both the α- and β-forms of HA₆ and determined the mole abundance ratio of these two forms to be 60% α and 40% β [35]. Since α-HA₆ was more abundant in the mixture, and had considerably better resolution than β-HA₆, it was decided at this stage to determine the dynamic 3D-structure of α-HA₆ rather than β-HA₆.

²J_(HH) and ³J_(HH) coupling constants have been measured in GlcA and GlcNAc rings in a variety of HA oligosaccharides, giving consensus values for each coupling constant in these residue types (FIG. 15) [35].

Analysis of Spectral Lineshapes

Four different NOESY and T-ROESY datasets were used to provide structural restraints for α-HA₆. These were a 2D-[¹H, ¹H]-NOESY dataset, a 2D-[¹H, ¹H]-T-ROESY dataset, a 3D [¹H, ¹⁵N]-NOESY-HSQC dataset and a 3D-[¹H, ¹⁵N]-FT-ROESY-HSQC dataset; full details of the acquisition parameters for each dataset are given below. Scaling factor sets were determined for each of these datasets as follows. The ²J_(HH) and ³J_(HH) scalar couplings of all protons within α-HA₆, which are required for the broadening adjustment formula, were taken from FIG. 15.

The 2D-[¹H, ¹H]-NOESY dataset was recorded with sufficient data points in the acquisition dimension to resolve proton multiplet splitting, but with small enough number of data points in the indirect dimension to prevent these multiplets from being resolved (i.e., simplifying the analysis of proton multiplets to just the acquisition dimension, as described above). The value of λ (this line-width of resonances in Hz, see above) for this dataset was determined by measurement of NOESY cross-peaks to amide and GlcA H1 protons, which all manifest as simple doublets (each doublet component therefore giving a true measure for λ). Values of 4.83, 4.75, 5.28 and 5.21 Hz were measured from the separate resonances in each doublet, giving an average value for λ of 4.8 Hz. This value for λ, the scalar coupling constants (FIG. 15) and the broadening adjustment formula were used to determine scaling-factor sets for each proton in α-HA₆ in this 2D-[¹H, ¹H]-NOESY dataset as follows:

GlcA rings 1,3 & 5, H1 proton: since this proton has only one ³J_(HH) coupling-constant of 7.8 Hz, which is bigger than λ, it manifests in the acquisition dimension of this 2D-NOESY spectrum as a simple doublet (i.e., as FIG. 9, one scalar-coupling). The scaling factor set for each component in the doublet is therefore 2, i.e. ƒ_(i)={2, 2}.

GlcA rings 1,3 & 5, H2 proton: this proton has two ³J_(HH) coupling-constants of 9.5 Hz and 7.8 Hz, which results in a basic appearance of a triplet for this proton (i.e., as FIG. 10, two scalar-couplings), i.e. an initial scaling factor set of ƒ_(i)={4, 2, 4}. However, since the two coupling constants are not identical, the two middle multiplet components do not exactly overlap and the central peak of the ‘triplet’ is broadened. The separation Δv between these middle components is (9.5−7.8)=1.7 Hz, which is considerably less than λ, and the broadening on this component is determined by the broadening adjustment formula as (4.8/(4.8−1,7/2))=1.2. This broadening adjustment is multiplied by the overlap-adjustment factor (i.e., 2), to give the combined scaling factor (see above) for the central peak in the resonance multiplet as 2.4. The scaling factor set for each component in the triplet of this proton is therefore ƒ_(i)={4, 2.4, 4}.

GlcA rings 1,3 & 5, H3 proton: similarly to GlcA H2 protons, this proton has two ³J_(HH) coupling-constants of different values, namely of 9.5 Hz and 8.8 Hz. Following the same process for GlcA H2, it can be seen that the basic triplet appearance with initial scaling factors pattern ƒ_(i)={4, 2, 4} also needs to be corrected for the broadening on the central peak caused by the non-identity of the two coupling constants. The difference Δv in Hz between the couplings (1.3 Hz) gives an broadening adjustment factor of 1.1, resulting in a corrected scaling-factor set of ƒ_(i)={4, 2.2, 4}.

GlcA rings 1,3 & 5, H4 proton: this proton has two ³J_(HH) coupling-constants of values 9.7 and 8.8 Hz. Following the same reasoning as for GlcA H2 and H3 protons leads to the scaling factor set of ƒ_(i)={4, 2.2, 4}.

GlcA rings 1,3 & 5, H5 proton: this proton has only one ³J_(HH) coupling-constant of 7.8 Hz, which is bigger than λ. It is therefore a simple doublet (i.e., as FIG. 9, one scalar-coupling) with a scaling-factor set of ƒ_(i)={2, 2}.

GlcNAc rings 2 & 4, H1 proton: This proton has only one ³J_(HH) coupling-constant of 8.5 Hz, which is bigger than λ. (i.e., as FIG. 9, one scalar-coupling) with a scaling-factor set of ƒ_(i)={2, 2}.

GlcNAc rings 2 & 4, H2 proton: this proton has three ³J_(HH) coupling-constants in H₂O of 10.4 Hz, 9.7 Hz and 8.5 Hz, which results in a basic appearance of a quartet (i.e., as FIG. 10, three scalar-couplings) for this proton, i.e. an initial scaling factor set of ƒ_(i)={8, 2.7, 2.7, 8}. While the two exterior multiplet components are clearly resolved and retain the initial scaling factors of 8, the inner pair of components in the quartet are somewhat broadened by the non-equality of the 3 coupling constants. Analysis of broadending adjustments in this case is quite involved but, by treating the overlap as two successive pairs of overlapping multiplet components, the broadening formula indicates the central resonances are to be further scaled by a factor of 1.4. The corrected scaling factor set is therefore ƒ_(i)={8, 3.8, 3.8, 8}.

GlcNAc rings 2&4, H3 proton: has two ³J_(HH) coupling-constants of values of 10.4 Hz and 8.7 Hz (therefore appears as FIG. 10, two scalar-couplings) giving an initial scaling factor set of ƒ_(i)={4, 2, 4}. Application of the broadening formula to the central resonance as before results in the corrected scaling-factor set of ƒ_(i)={4, 2.4, 4}.

GlcNAc rings 2&4, H4 proton: has two ³J_(HH) coupling constants of values of 9.9 Hz and 8.7 Hz. The correct scaling factor accounting for the broadening on the central resonance is therefore ƒ_(i)={4, 2.4, 4}.

GlcNAc rings 2&4, H5 proton: has four different ³J_(HH) coupling-constants, which results in multiple overlaps and makes the resonance appear as a broad plateau with 4 resonances (most like FIG. 9, two scalar-couplings). The scaling factor for this proton was calculated to be ƒ_(i)={2.8, 2.8, 2.8, 2.8} from consideration of the overlapping multiplet components, see FIG. 11.

GlcNAc rings 2&4, H6proS proton: has one ²J_(HH) and one ³J_(HH) coupling-constant, of values of −12.3 Hz and 2.3 Hz, and therefore manifests as a doublet of broadened resonances (i.e., most like FIG. 9, one scalar-coupling in appearance), giving an initial scaling factor set of ƒ_(i)={2, 2}. The broadening on each resonance is caused by the small 2.3 Hz coupling, which results in a broadening adjustment for each scaling factor of 1.3. The correct scaling factor set for this proton is therefore ƒ_(i)={2.6, 2.6}.

GlcNAc rings 2&4, H6proR proton: has one ²J_(HH) and one ³J_(HH) coupling-constant, of values of −12.3 Hz and 5.4 Hz, and manifests as a four clearly-resolved resonances due to the frequency differences between them and λ (i.e., looks most like FIG. 9, two scalar-couplings). The scaling factor set for this proton is therefore ƒ_(i)={4, 4, 4, 4}.

GlcNAc rings 2&4, HN proton: This proton has only one ³J_(HH) coupling-constant of 9.7 Hz, which is bigger than λ. It is therefore a simple doublet (i.e., most like FIG. 9, one scalar-coupling) with scaling factor set of ƒ_(i)={2, 2}.

In the case of GlcNAc ring 6, the different coupling constant between protons H1 and H2 (see FIG. 15) compared to GlcNAc rings 2&4 results in slightly different scaling factor sets for H1 and H2 protons compared to GlcNAc rings 4 and 6. Moreover, all scaling factors are multiplied by the mole abundance 1/r (r=0.6) scaling ratio of 1.7 to compensate for the α-anomer only being at 60% mole abundance.

GlcNAc ring 6, H1 proton: This proton has only one ³J_(HH) coupling-constant of 3.5 Hz, which is smaller than λ. It therefore manifests in the spectrum as a broadened singlet (i.e., most like FIG. 9, one scalar-coupling), with a broadening adjustment 1.6. Its scaling factor set is therefore ƒ_(i)={1.6} and, after mole abundance scaling, ƒ_(i)={2.7}.

GlcNAc ring 6, H2 proton: this proton has three ³J_(HH) coupling constants in H₂O of 10.4, 9.7 and 3.5 Hz, which results in a basic appearance of a triplet for this proton (i.e., most like FIG. 10, two scalar-couplings) with multiple broadenings, giving an initial scaling factor set of ƒ_(i)={4, 2, 4}. The outer two resonances are broadened by the 3.5 Hz coupling, given a broadening adjustment of 1.6 in both cases. The inner resonance is broadened principally by the 3.5 Hz coupling with a broadening adjustment of 1.6, but the 0.7 Hz difference between the two large couplings also contributes with an additional broadening adjustment of 1.1, giving a net of 1.7. The scaling factor for the central resonance is therefore 3.4. The scaling factor set is therefore ƒ_(i)={6.2−3.4−6.2} and after mole abundance scaling, ƒ_(i)={10.5, 5.8, 10.5}.

GlcNAc ring 6, H2, H3, H4, H5, H6proS, H6proR protons: Since these protons have the same coupling constants as GlcNAc rings 2&4, they have the same scaling factor sets as in GlcNAc rings 2&4, but each scaling factor in each scaling factor set is multiplied by the mole abundance scaling ratio of 1.7.

In summary, the scaling factor sets for proton resonance multiplets in the 2D [¹H, ¹H]-NOESY dataset were as follows:

GlcA GlcNAc GlcNAc rings 1, 3 5 rings 2, 4 ring 6 H1 {2, 2} H1 {2, 2} H1 {2.7} H2 {4, 2.4, 4} H2 {8, 3.8, 3.8, 8} H2 {10.5, 5.8, 10.5} H3 {4, 2.2, 4} H3 {4, 2.5, 4} H3 {6.8, 4.3, 6.8} H4 {4, 2.2, 4} H4 {4, 2.3, 4} H4 {6.8, 3.9, 6.8} H5 {2, 2} H5 {2.8, 2.8. 2.8, H5 {4.8, 4.8. 4.8, 4.8} 2.8} H6proS {2.6, 2.6} H6proS {4.4, 4.4} H6proR {4, 4, 4, 4} H6proR {6.8, 6.8, 6.8, 6.8} HN {2, 2} HN {3.4, 3.4}

The 2D [¹H, ¹H]-T-ROESY dataset was recorded with sufficient data points in the acquisition dimension to resolve proton multiplet splitting, but with small enough number of data points in the indirect dimension to prevent these multiplets from being resolved. The spectral line-width (λ) of this dataset was determined to be 6.5 Hz in an manner analogous to that for the 2D [¹H, ¹H]-NOESY dataset described above. Following a process similar to that described above, the scaling factor sets for this 2D-T-ROESY spectrum were calculated to be as follows:

GlcA GlcNAc GlcNAc rings 1, 3 5 rings 2, 4 ring 6 H1 {2, 2} H1 {2, 2} H1 {2.7} H2 {4, 2.3, 4} H2 {4, 2.4, 4} H2 {6.0, 6.0} H3 {4, 2.1, 4} H3 {4, 2.3, 4} H3 {6.8, 4.1, 6.8} H4 {4, 2.2, 4} H4 {4, 2.2, 4} H4 {6.8, 3.7, 6.8} H5 {2, 2} H5 {2.4, 2.4. 2.4, H5 {4.1, 4.1. 4.1, 4.1} 2.4} H6proS {2.3, 2.3} H6proS {3.9, 3.9} H6proR {3.4, 3.4} H6proR {5.8, 5.8} HN exchanged HN exchanged

The first notable difference between the scaling factor sets for this spectrum and for the 2D-NOESY described above is that the amide protons have no scaling factors—this arises because the spectrum was recorded on a 100% D₂O α-HA₆ sample, and therefore the amide protons completely exchange with solvent deuterons and become NMR-inactive. The second notable difference is that the GlcNAc H2 proton on rings 2 and 4 only have two ³J_(HH) scalar-coupling constants present (the amide proton has exchanged), resulting in a initial triplet scaling-factor set (i.e., most like FIG. 10, two scalar-couplings), rather than the quartet seen for H₂O samples.

The 3D [¹H, ¹⁵N]-NOESY-HSQC dataset was recorded with sufficient data points in the acquisition dimension to resolve proton multiplet splitting, but with small enough number of data points in the indirect dimension to prevent these multiplets from being resolved. Scaling factor sets need only be determined for the amide proton in this dataset, since it does not contain peaks from any other proton in α-HA₆. Since each amide proton is coupled to a ring H2 proton with scalar-couplings of ˜9.5 Hz (see FIG. 15) and value of λ of this dataset was 6 Hz, each NOE manifests as a simple doublet of resonances in the spectrum, i.e. initial scaling factors sets of ƒ_(i)={2, 2}. In the case of the amide proton in ring 6, each scaling factor in the initial scaling-factor set must be multiplied by the mole abundance scaling (=1.7), i.e., the scaling factor set for ring 6 is ƒ_(i)={3.3, 3.3}. The scaling factor sets for rings 2 and 4 are not adjusted by mole abundance ratios, and therefore remain as ƒ_(i)={2, 2}.

The 3D [¹H, ¹⁵N]-T-ROESY-HSQC dataset was acquired with very similar parameters to the 3D [¹H, ¹⁵N]-NOESY-HSQC and therefore had the same scaling factors sets.

Measurement and Quantitation of NMR Spectra

Five different kinds of NMR data in seven different experimental NMR datasets were used in the determination of the dynamic solution structure of α-HA₆. These restraints were used by the optimisation algorithm to find the best values for the 13 unknown variables (see above). The five kinds of NMR data used were:

-   -   1) NOESY relaxation data: two experimental datasets, 1) [¹H,         ¹⁵N]-NOESY-HSQC, 2) [¹H, ¹H]-2D-NOESY     -   2) T-ROESY relaxation data: two experimental datasets, 1) [¹H,         ¹⁵N]-T-ROESY-HSQC, 2) [¹H, ¹H]-2D-NOESY     -   3) conformation-dependent scalar couplings: one experimental         dataset     -   4) residual dipolar couplings (RDCs): one experimental dataset     -   5) order parameters (calculated from [¹H, ¹⁵N]-heteronuclear-NOE         and T₁-measurements): one experimental dataset.

The pertinent acquisition parameters for each of these different NMR datasets, and the number of structural restraints measured from them, were as follows (all datasets were acquired at 298K).

The 2D [¹H, ¹H]-NOESY spectrum was recorded on a sample of 5 mM HA₆ (95% H₂O, pH 6.0, 0.3 mM DSS) at 900 MHz with a NOE mixing time of 400 ms and sweep widths of 10800 Hz in both dimensions. Using the scaling factor sets described above, true peak-heights for each NOE peak were determined, resulting in 82 NOE structural restraints. Errors on each NOE restraint were using the initial m value of 0.4 for a 2D-NOESY spectrum. 94 noNOE structural restraints were also measured from this spectrum, following the methodology described above. These NOE and noNOE structural restraints were contained in the dataset file given in Appendix A.

The 3D [¹H, ¹⁵N]-NOESY-HSQC spectrum was recorded on a sample of 12 mM ¹⁵N-labelled HA₆ (95% H₂O) at 600 MHz (NOE mixing time 400 ms, sweep width of 7200 Hz for both proton dimensions, 140 Hz for ¹⁵N dimension, ¹⁵N offset at 122.5 ppm), as described previously [8, 36]. Using the scaling factor sets detailed above, the true peak-height for one mole abundance for each NOE cross-peak and diagonal-peak was determined. The m value for the 3D [¹H, ¹⁵N]-NOESY-HSQC spectrum was set to 0.4, enabling the errors on the true peak heights to be calculated as described above. 19 NOE restraints were measured from this spectrum, which are given in the dataset file in Appendix A.

The 2D [¹H, ¹H]-T-ROESY spectrum was recorded on a sample of 20 mM HA₆ (100% D₂O, pH 6.0, 0.3 mM DSS) at 600 MHz with a NOE mixing time of 400 ms and sweep widths of 7200 Hz in both dimensions. Using the scaling-factor sets, described above, 62 ROE structural restraints were measured from this spectrum. Errors on each ROE restraint were determined as described above, using the initial m value of 0.5 for a 2D [¹H, ¹H]-T-ROESY spectrum. 63 noROE structural restraints were also measured from this spectrum. These ROE and noROE structural restraints were contained in the dataset file given in Appendix A.

The 3D [¹H, ¹⁵N]-T-ROESY-HSQC spectrum was recorded on a sample of 12 mM ¹⁵N-labelled HA₆ (95% H₂O) at 600 MHz (ROE mixing time 400 ms, sweep width of 7200 Hz for both proton dimensions, 140 Hz for ¹⁵N dimension, ¹⁵N offset at 122.5 ppm). Errors on each ROE restraint were determined with the formula as described above, using the initial m value of 0.2 for a 3D [¹H, ¹⁵N]-T-ROESY-HSQC spectrum. 18 ROE structural restraints were measured from this spectrum, as listed in the dataset file given in Appendix A.

Conformation-dependent scalar coupling constants for the acetamideo sidechain groups (³J_(2,HN)) in α-HA₆ have been measured previously (see FIG. 15) [35]. As noted above, the coupling constant for ring 6 was observed to have a slightly different value to that of rings 2 and 4. The best Karplus equation for relating these coupling constants to the dihedral angle in the molecule is given by quantum mechanical calculations, as described previously [37]. The combined error in measurement of the coupling (˜0.3 Hz) and predictive accuracy of these Karplus relations (˜0.3 Hz) is ˜0.5 Hz. The three scalar coupling constants were contained in the dataset file given in Appendix A.

Residual dipolar coupling data for α-HA₆ has not been previously reported and was therefore measured de novo for this work following the methods using high-resolution 1D NMR-spectra and natural abundance [¹H, ¹³C]-HSQC/[¹H, ¹⁵N]-HSQC spectra described above. A [¹H, ¹³C]-HSQC spectrum (without ¹³C-broadband decoupling during acquisition) was recorded at natural abundance in the absence of alignment media (as we have described previously [35]) on a 20 mM sample of HA₆ in 50% D₂O for the measurement of the one-bond C—H and overlapped H—H coupling constants. A second [¹H, ¹³C]-HSQC spectrum was recorded at natural abundance with identical acquisition parameters on a sample containing alignment media (5 mM sample of HA₆ in 50% D₂O, with alignment phage present at 3 mg/ml). 31 non-overlapped RDCs (numbers 1 to 31 in the list in Appendix A) and 27 overlapped RDCs were measured from the [¹H, ¹³C]-HSQC spectra (numbers 101 to 127 in the list in Appendix A). Three more non-overlapped RDCs (numbers 131 to 132 in the list in Appendix A) were obtained on the same samples from [¹H, ¹⁵N]-HSQC spectra recorded at natural abundance. Three additional non-overlapped RDCs were measured from high-resolution 1D NMR spectra (numbers 128 to 130 in the list in Appendix A). The standard error on each RDC structural restraint was determined to be 0.35 Hz using the methodology described above. These RDCs (65 in total) were contained in the dataset file given in Appendix A.

Order parameters and their errors for the three acetamido N—H groups in α-HA₆ have been measured previously [22]. The three order parameters were contained in the dataset file given in Appendix A.

Molecule Specification

The experimental datasets described above were acquired in two different solvents, namely H₂O and D₂O. The solvent mask (see above) for each of these was determined as follows:

-   -   1) H₂O solvent mask: all hydroxyl protons in α-HA₆ exchange very         rapidly with solvent protons, so these protons were all defined         as NMR-inactive (exc*HO*). The amide protons exchange         sufficiently slowly to be observable, i.e., are NMR-active [34].         All other protons were defined as active (add*H*).     -   2) D₂O solvent mask: all hydroxyl (exc*HO*) and amide protons         (exc*H₂N) in α-HA₆ completely exchange with solvent deuterons,         so these protons were all defined as NMR-inactive. All other         protons were defined as active (add*H*).

The actual file used to specify these two solvent masks was as follows:

remark Solvent masks for alpha-HA6 conditions: solvents 2 endsection solvent: name h2o add * H* exc * HO* endsection solvent: name d2o add * H* exc * HO* exc * H2N endsection

The locations of various atoms within α-HA₆ relative to the rest of the molecular structure could not be specified from the experimental data available (namely the two oxygen atoms in each carboxylate group and all the hydroxyl protons). While these atoms were retained in the molecule for the sake of visual reality, it was necessary that their (arbitrarily defined) internal coordinates should not affect the structure calculations by adverse van der Waals interactions. These atoms were therefore set to be van der Waals inactive by the following van der Waals mask:

remark Van der Waals mask for alpha-HA6 configuration: vdw.cutoff 6.0 vdw.coupling 1e−4 endsection nonbonded: vdw * H* 0.016 0.60 vdw * C* 0.100 1.91 vdw * N* 0.170 1.92 vdw * O* 0.210 1.66 remark exclude all hydroxyl protons exc * HO* remark exclude the oxygen atoms in the carboxylate groups exc * O6A exc * O6B endsection

Experimental Data Input

The value of τ_(c) was set to 0.4 ms for all rounds of structure calculations, having been experimentally determined as described previously [22]. The various experimental datasets described above were recorded on NMR samples containing different H₂O/D₂O solvent mixtures (see above), and therefore the adjusted solvent viscosities for each dataset were calculated using equations (22) and (23). The seven experimental dataset files used in the structure calculations are given in Appendix A.

Dynamic Model

The pertinent conformationally-flexible bonds and chemistries within α-HA₆ were identified, using the methodology described above, as being (see FIG. 16):

-   -   1) each of the six carbohydrate rings could exist in a variety         of conformations, for example chair, boat or skew-boat         conformation.     -   2) the three β1→3 glycosidic linkages, i.e. the linkages between         rings 1&2, 3&4 and 5&6. Each chemical bond on either side of the         linkage oxygen atom has an undefined dihedral angle, designated         phi (φ) and psi (φ) respectively.     -   3) the two β1→4 glycosidic linkages, i.e. the linkages between         rings 2&3 and 3&4. Each chemical bond on either side of the         linkage oxygen atom has an undefined dihedral angle, designated         phi (φ) and psi (φ) respectively.     -   4) the three acetamido sidechain groups can rotate with respect         to their GlcNAc rings (rings 2, 4 and 6) about each         N(nitrogen)-C2(ring) bond.     -   5) the three acetamido sidechain groups (rings 2, 4 and 6) can         exist in either cis or trans conformations at the amide         N(nitrogen)-C(carbonyl) bond.     -   6) the three methyl groups on the acetamido sidechain groups         (rings 2, 4 and 6) can rotate with respect to their acetamido         sidechains about the C(methyl)-C(carbonyl) bond.     -   7) the three hydroxymethyl sidechain groups can rotate with         respect to their GlcNAc rings (rings 2, 4 and 6) about the         C6(hydroxymethyl)-C5(ring) bond.     -   8) The three carboxylate groups can rotate with respect to their         GlcA rings (rings 1, 3 and 5) about the C(carboyxlate)-C5(ring)         bond.     -   9) all the hydroxyl groups in all the GlcNAc and GlcA rings can         rotate about their respective O(oxygen)-C(carbon) bonds.

To create a realistic dynamic model of the molecule upon which to compare against the observed experimental data, degrees of freedom were modelled as follows:

-   -   1) the large values for the ³J_(HH) coupling constants in both         GlcA and GlcNAc rings indicate that the rings adopt a ⁴C₁ chair         conformation in aqueous solution, and do not appreciably         interconvert with other forms [36]. Each carbohydrate ring was         therefore modelled in a rigid ⁴C₁ chair conformation.     -   2) the two β1→3 glycosidic linkages between rings 1 &2 and 3&4         have been shown by the analysis of chemical shifts and NOE         patterns to adopt virtually identical (though unknown)         conformations in aqueous solution, without any experimental         evidence for the presence of multiple stable, interchanging         conformations [8, 34, 36]. These two β1→3 linkages were         therefore represented with the same variables, which were a         single unimodal conformation probability distribution for each         of the phi (φ) and psi (φ) angles (i.e., two mean values, μ_(φ),         and μ_(φ), for linkages between 1&2 and 3&4) and, since these         two dihedral angles are directly coupled together dynamically,         they were given the same standard-deviation angle of local         libration (σ). The β1→3 glycosidic linkage between rings 5&6         (the ‘alpha’ linkage) has been shown by the analysis of chemical         shifts, NOE patterns and molecular dynamics simulations to be         likely to be adopting a different conformation in solution from         the other two β1→3 linkages [8, 34, 36]. This linkage was         therefore modelled in the same way as the other β1→6 linkages         (i.e., two mean values, μ_(φ) & μ_(φ) having the same standard         deviation angle of local libration σ), but had variables         independent of the other two β1→3 linkages.     -   3) The two β1→4 glycosidic linkages have been shown by the         analysis of chemical shifts and NOE patterns to adopt virtually         identical (though unknown) conformations in aqueous solution,         without any experimental evidence for the presence of multiple         stable, interchanging conformations [8, 34, 36]. The two β1→4         linkages were therefore represented with the same variables,         namely a single unimodal conformation probability distribution         for each of the phi (φ) and psi (φ) angles (i.e., μ_(φ) and         μ_(φ), for linkages between 2&3 and 4&5) with the same standard         deviation angle of local libration (σ).     -   4) All the acetamido sidechain groups in rings 2 and 4 have been         shown to be adopting an approximately trans conformation with         respect to the ring (i.e., HN—N—C2-H2 dihedral=180°, although         the amide group in ring 6 has been shown to be different to the         other two by a small but unknown amount [8, 34, 36]. There is no         experimental evidence from either assignment spectra or NOE         restraints for the presence of multiple conformations for any         amide group [8, 35]. The acetamido sidechains were therefore all         modelled with unimodal conformation probability distributions.         Since the acetamido sidechains in rings 2 and 4 are         indistinguishable in solution, the same variables were used for         both of them (μ_(HN), σ_(HN) in residues 2 & 4), whereas the         acetamido sidechain in ring 6 was modelled with independent         variables (∥_(HN), σ_(HN) for residue 6).     -   5) The amide bonds in the three acetamido sidechain groups were         set to be in the trans conformations, since this is the expected         geometry for this chemical group in the absence of other forces,         and is the state found in monosaccharide GlcNAc [38].     -   6) Methyl groups rotate freely around the C—C bond, with the 3         staggered rotamer positions being slightly favoured over         semi-eclipsed states. This motion was modelled by a trimodal         conformation model, in which the dihedral angle was given three         values (0°, 120° and 240°, corresponding to the 3 staggered         rotamer positions) with an equal probability of being in each         conformation. In addition, the local libration was set to a         fixed value of 30° for each conformation.     -   7) The three hydroxymethyl sidechain groups have been shown to         be adopting indistinguishable conformations from each other in         aqueous solution by comparison of chemical shifts and         ³J_(5,6proS) and ³J_(5,6proR) couplings constants [35].         According to the relation of Hasnoot et al. [15], the values         observed for these two couplings (see FIG. 15) indicate that         each hydroxymethyl group is rapidly interchanging between two         conformers (termed gg and gt) in a 50:50% ratio. This motion was         therefore modelled with a bimodal conformational model, in which         the dihedral angle was given the two appropriate values for gg         and gt with an equal probability of being in each conformation,         and a fixed local libration of 15° for each conformation (i.e.,         an appropriate value based upon our experience of other systems         since there was insufficient experimental data to determine this         value more precisely).     -   8) There was no experimental data available to restrain the         conformations of the three carboxylate groups (the oxygen atoms         are NMR-inactive), so the positions of the two oxygen atoms in         each group could not be determined with respect to the rest of         the molecule. The carboxlate groups were therefore all given the         same arbitrary value and, in order to prevent them from         influencing the structure calculation by steric clashes that may         have arisen because of a poor choice of the arbitrary value,         they were set to not contribute to any van der Waals repulsions         (see above). Fortunately, rotations of the carboxylate groups do         not affect the overall shape or dynamic motions of α-HA₆. In         addition, since all experiments were performed at pH 6.0, the         carboxylate groups were modelled in the unprotonated state [36].     -   9) Similarly, there was no experimental data available to         restrain the conformations of any of the hydrogen atoms in the         hydroxyl groups (they exchange with solvent water very rapidly),         so the positions of the hydrogen atoms in each hydroxyl group         could not be determined with respect to the rest of the         molecule. The hydroxyl protons were therefore given arbitrary         values and made van der Waals inactive to prevent them from         influencing the structure calculation by unfortunate steric         clashes that may have arisen due to a poor choice of the         arbitrary value.

The specific implementation of these considerations was achieved using the following dynamic-model file:

remark Dynamic model of alpha-HA6 variables: remark b1-3 linkages rings 1-2 & 3-4 means var 1 rand 0 360 jump 180 var 2 rand 0 360 jump 180 remark b1-3 linkages rings 1-2 & 3-4 Gaussain spread var 3 fix 18 jump 10.0 start 0.3 remark b1-3 linkage rings 5-6 mean var 4 rand 0 360 jump 180 var 5 rand 0 360 jump 180 remark b1-3 linkage rings 5-6 Gaussian spread var 6 fix 18 jump 10.0 start 0.3 remark b1-4 linkages rings 2-3 & 4-5 means var 7 rand 0 360 jump 180 var 8 rand 0 360 jump 180 remark b1-4 linkages rings 2-3 & 4-5 Gaussian spread var 9 fix 18 jump 10.0 start 0.3 remark amides rings 2&4 mean var 10 fix 119.5 jump 2.0 start 0.3 remark amides rings 2&4 Gaussian spread var 11 fix 24 jump 10.0 start 0.3 remark amide ring 6 mean var 12 fix 119.5 jump 2.0 start 0.3 remark amide ring 6 Gaussian spread var 13 fix 24 jump 10.0 start 0.3 remark hydroxymethyls rings 2&4&6 mean var 14 fix −60 jump 0.0 start 0.0 var 15 fix 60 jump 0.0 start 0.0 remark hydroxymethyl rings 2&4&6 Gaussian spread var 16 fix 15 jump 0.0 start 0.0 remark methyl groups rings 2&4&6 means var 17 fix −120 jump 0.0 start 0.0 var 18 fix 120 jump 0.0 start 0.0 var 19 fix 0 jump 0.0 start 0.0 remark methyl Gaussian rings 2&4&6 spread var 20 fix 30 jump 0.0 start 0.0 endsection probabilities: remark hydroxymethyl groups rings 2&4&6 bimodal distribution mode 1 2 0.5 0.0 remark methyl groups rings 2&4&6 trimodal distribution mode 2 3 0.33 0.66 0.0 endsection dynamics: remark b1-3 linkages rings 1-2 & 3-4 gyrate 41 1 3 gyrate 42 2 3 gyrate 93 1 3 gyrate 94 2 3 remark b1-3 linkage rings 5-6 gyrate 146 4 6 gyrate 147 5 6 remark b1-4 linkages rings 2-3 & 4-5 gyrate 70 7 9 gyrate 71 8 9 gyrate 122 7 9 gyrate 123 8 9 remark amides rings 2&4 gyrate 31 10 11 gyrate 83 10 11 remark amide ring 6 gyrate 136 12 13 remark hydroxymethyls rings 2&4&6 multigyrate 48 1 14 16 15 16 multigyrate 100 1 14 16 15 16 multigyrate 153 1 14 16 15 16 remark methyl groups rings 2&4&6 multigyrate 35 2 17 20 18 20 19 20 multigyrate 87 2 17 20 18 20 19 20 multigyrate 140 2 17 20 18 20 19 20 endsection

In the variables section of this file, 20 variables are defined (var 1 to var 20) and which of these variable were used for each rotatable bond in α-HA₆ is shown in FIG. 17. Two variables (var 4 and var 5) are assigned to the β1→6 linkages between rings 5 and 6 (remark b1-3 linkages ring 5-6 mean) for the mean values of the φ and φ dihedral angles, respectively, and one variable (var 6) is assigned to their common Gaussian spread (remark b1-3 linkage rings 5-6 Gaussian spread). These φ and φ mean dihedral angles are both given a random value between 0° and 360° (rand 0 360) at the start (start 0.0) of the iterative optimisation, while the Gaussian spread is assigned a specific (and reasonable) value of 20° (fix 20) at the start of the optimisation, which is varied at each step of the iteration by a random amount up to 10° (jump 10.0) from the start of the optimisation (start 0.0). The other two β1→6 linkages are similarly specified (var 1, var 2 and var 3) and, because they are given the same variables, they are modelled as being dynamically and conformationally identical to each other. The unimodal distributions for the φ and φ bonds in the two β1→4 linkages are similarly specified by variables 7 to 9. The unimodal distributions for the acetamido sidechains C2-N2 bond are similarly specified by variables 9 and 10 (sidechains in rings 2 and 4) and 11 and 12 (sidechain in ring 6). The hydroxymethyl groups all have the same bimodal angular distribution. The two mean dihedral angles of for this bimodal distribution are specified with var 14 and var 15, which are both fixed (jump 0.0) from the start (start 0.0) of the optimisation, and they both have the same Gaussian spread (var 16) of 15° (fix 15.0) that does not vary throughout the optimisation (jump 0.0). The methyl groups all have the same trimodal angular distribution. The three mean dihedral angles for this trimodal distribution are specified with var 17, var 18 and var 19, which are all fixed (jump 0.0) from the start (start 0.0) of the optimisation, and they all have the same Gaussian spread (var 20) of 30° (fix 30.0) that does not vary throughout the optimisation (jump 0.0). These variables are mapped to particular dihedral angles within the molecule using the probabilities, gyrations and multigyrations (as described above).

In this manner, all the flexible parts of the α-HA₆ molecule and their behaviour are defined for the computer, according to the analysis of the nine degrees of freedom given above. Since variables 14 to 20 have a predefined fixed value, there are therefore 13 distinct unknown molecular variables to determine in order to solve the solution structure of α-HA₆.

Structure Calculations

Each round of structures calculations for α-HA₆ comprised 40 runs. Statistics were performed on the lowest 10 χ² _(total) runs. Each individual run had 10,000 iteration steps and the dynamic ensemble was composed of 100 structures. The seven experimental dataset files (see Appendix A) were brought in progressively in successive rounds of structure calculations, as described below.

The initial 3D-model of the HA hexasaccharide was constructed based on knowledge of standard bond distances, angles and chemistries for the parts of the molecule that were in a fixed geometrical relationship (as described above). In the initial rounds of structure calculations (rounds 1 through 30), four dataset files were used to determine a rough solution conformation for α-HA₆. These were:

-   -   1) the order parameters dataset file (3 structural restraints)     -   2) the scalar couplings dataset file (3 structural restraints)     -   3) the ¹⁵N-NOESY-HSQC dataset file (19 structural restraints)     -   4) the 2D-NOESY dataset file (82 NOE structural restraints).

The structural restraints in the order parameters, scalar couplings and ¹⁵N-NOESY-HSQC dataset files were relatively few and easily generated and therefore very unlikely to contain any mistakes and could all be included right from the start of the structure-determination process. In contrast, the large 2D-NOESY dataset file was expected to contain many mistakes, and therefore only the most certain NOE structural restraints were used in the first round of calculations (˜60 restraints), and no ‘noNOE’ structural restraints were used. After 30 rounds of structure calculations, the erroneous NOE structural restraints in the 2D-NOESY dataset had been corrected, and all NOE structural restraints had been included. The top 10 of the 40 runs in this round all gave similar values for the 10 unknown variables, as shown in the statistics below:

Round30 statistics: Ranked run no. Parameter Mean StDev 22 27 24 10 12 11 5 15 9 26 15N-NOE 108.3 4.3 98.6 103.2 106.8 110.5 111.0 112.5 107.5 112.1 108.2 112.4 2D-NOE 29.6 1.6 31.1 28.6 28.2 29.1 27.3 28.8 33.2 28.9 30.9 29.6 JCOUP 2.6 0.9 2.2 2.7 2.2 2.3 1.6 2.9 3.5 4.4 3.6 1.1 ORDER 2.2 1.5 2.0 2.2 1.5 1.1 2.5 0.2 2.0 0.4 4.5 5.3 VDW 1.3 0.9 2.5 1.9 2.6 0.5 1.7 1.7 0.2 1.0 0.5 0.3 TotChi 143.9 3.8 136.5 138.6 141.2 143.5 144.1 146.0 146.5 146.7 147.6 148.7 1-3_phi −83.4 8.9 −95.2 −74.3 −88.5 −76.4 −92.8 −96.2 −75.7 −73.2 −74.8 −87.1 1-3_psi −119.3 5.2 −115.3 −122.9 −112.0 −123.6 −114.5 −121.6 −124.7 −112.1 −119.8 −126.8 1-3_dyn 20.9 5.5 18.8 24.4 11.5 25.1 16.3 23.2 25.9 12.4 27.5 23.9 a1-3_phi −58.4 25.7 −71.6 −61.1 −84.3 −57.0 −87.2 −58.4 0.3 −31.6 −49.0 −83.9 a1-3_psi −129.7 5.2 −131.2 −129.8 −122.9 −126.8 −127.5 −133.9 −135.8 −133.9 −135.6 −119.4 a1-3_dyn 16.7 3.5 17.2 15.1 15.8 17.1 18.7 20.5 17.1 22.1 14.7 8.4 1-4_phi −91.9 8.8 −97.4 −110.2 −89.0 −91.2 −93.9 −77.8 −97.3 −88.4 −93.6 −79.8 1-4_psi −129.3 16.5 −150.5 −140.2 −121.3 −108.2 −117.0 −113.1 −153.9 −148.0 −112.6 −127.8 1-4_dyn 18.9 3.0 18.5 17.3 24.0 16.6 21.4 15.5 20.2 23.2 15.2 17.2 HN 119.1 1.3 120.3 117.3 116.7 119.1 119.0 121.4 120.1 119.7 118.3 118.8 HN_dyn 32.3 1.6 33.7 34.3 31.4 32.0 35.4 30.2 30.5 31.8 31.8 32.3 HN_a 119.1 1.0 120.1 119.4 118.9 117.2 117.9 120.5 120.3 119.2 119.1 118.4 HN_a_dy 26.4 2.6 30.0 30.5 30.0 24.8 24.4 25.3 25.4 25.0 23.0 25.9

In this table, the output data from the top ten best χ² _(total) are shown, where run number 22 is the best and run number 26 is the 10^(th) best. Tot Chi line gives the χ² _(total) value for each run, as well as the mean value and standard deviation (StDev) for these χ² _(total) values. Above this line, the χ² _(total), mean and standard deviation values are given for each individual dataset file that was used in this round of calculations, i.e., the ¹⁵N-NOESY-HSQC(NOE-HSQC), 2D-NOESY (2D-NOESY), scalar coupling (JCOUP) and order parameters (ORDER). The χ² _(total), mean and standard deviation values are also given for the van der Waals (VDW) term in each run. Following the TotChi line are the results for the 10 variables var 1 to var 10 specified in the dynamic model file. After this round of calculations, therefore, the β1→3 linkages between rings 1&2 and 3&4 were found to have φ and φ angles of −83.4±8.9° (var 1) and −119.3±5.2° (var 2), respectively, with a Gaussian spread of 20.9±5.5° (var 3). The β1→3 linkage between rings 5&6 was found to have φ and φ angles of −58.4±25.7° (var 4) and −129.7±5.2° (var 5), respectively, with a Gaussian spread of 16.7±3.5° (var 6). The β1→4 linkage was found to have φ and φ angles of −91.9±8.8° (var 7) and −129.3±16.5° (var 8), with a Gaussian spread of 18.9±3.0° (var 9). The acetamido groups in rings 2 & 4 had a mean value of 119.1±1.3 (var 10) with a Gaussian spread of 32.3±1.6° (var 11), whilst that in ring 6 had a mean value of 119.1±1.0° (var 12) with a Gaussian spread of 26.4±2.6° (var 13).

In order to see if any one dataset file was unduly biasing the emerging structure, the χ² _(dataset)/restraint (Chi/Res) for each dataset and χ² _(total)/restraint was calculated:

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 107 142.3 1.3 0 0 2D-NOESY 82 107.9 1.3 0 0 JCOUP 3 2.6 0.9 0 0 15N-NOESY-HSQC 19 29.6 1.6 0 0 ORDER 3 2.2 0.7 0 0

In this case, it can be seen that the Chi/Res values are similar for each dataset (from 0.9 to 1.6), indicating that no one dataset file is dominating the others. Since the errors for the order parameters and scalar coupling data can be determined directly, while the errors for the NOESY dataset files depend upon the imprecisely known value m, of the value of m for the 2D-NOESY dataset (0.4) and ¹⁵N-NOESY-HSQC dataset (0.4) can be seen to be suitable. None of the 107 structural restraints used in this round of calculations were violators.

In the next ten rounds of structure calculations, the noNOE structural restraints from the 2D-NOESY spectrum were included. The results from the round of structure calculations where all noNOEs were included without any being violators, or any of the structural restraints in the other dataset files being violators, were as follows:

Round40 statistics: Ranked run no. Parameter Mean StDev 30 40 35 9 37 14 19 39 38 5 15N-NOE 27.6 1.1 28.1 28.0 27.1 27.7 26.6 29.0 26.5 29.7 27.0 26.4 2D-NOE 163.7 2.5 160.5 161.3 162.6 164.6 162.2 163.2 166.8 164.1 169.3 162.8 JCOUP 2.9 2.5 0.8 0.9 2.3 0.0 4.4 4.2 3.5 0.5 3.7 8.8 ORDER 1.9 1.2 0.8 2.0 0.9 1.8 1.7 1.5 1.3 4.3 0.5 3.8 VDW 0.5 0.3 0.8 0.4 1.0 0.1 0.5 0.3 0.6 0.6 0.8 0.3 TotChi 196.6 3.6 190.9 192.7 193.9 194.3 195.3 198.2 198.5 199.2 201.3 202.0 1-3_phi −62.7 8.2 −67.6 −64.3 −74.0 −58.0 −67.3 −60.7 −54.6 −44.3 −68.9 −67.4 1-3_psi −112.2 4.1 −117.3 −109.7 −111.6 −120.2 −109.5 −115.6 −106.5 −112.1 −108.3 −110.9 1-3_dyn 20.0 4.7 19.1 21.6 17.6 26.3 19.0 26.1 20.5 24.2 9.9 16.0 a1-3_phi −50.4 7.7 −57.7 −48.4 −64.2 −40.0 −52.0 −53.5 −40.2 −48.2 −42.5 −57.3 a1-3_psi −127.4 3.5 −124.5 −131.6 −125.9 −127.5 −129.0 −128.7 −122.5 −134.5 −124.3 −125.9 a1-3_dyn 15.7 2.8 10.2 20.4 13.8 17.0 15.1 15.0 19.0 15.6 13.5 17.6 1-4_phi −82.0 10.6 −79.3 −70.5 −87.5 −72.2 −92.7 −105.4 −84.9 −80.5 −68.8 −78.2 1-4_psi −131.4 15.1 −135.6 −156.8 −138.7 −130.6 −115.2 −117.3 −122.3 −150.5 −107.3 −139.4 1-4_dyn 18.7 5.1 22.0 13.8 20.0 9.0 17.2 14.7 18.9 19.2 28.2 23.7 HN 119.0 0.9 117.2 118.8 119.4 118.3 120.2 119.6 120.3 119.4 118.4 118.9 HN_dyn 31.5 1.9 31.1 32.0 28.8 30.7 34.1 30.1 35.1 32.4 29.4 31.0 HN_a 119.5 0.6 118.0 119.7 120.1 119.3 119.3 119.9 119.1 120.3 119.2 119.8 HN_a_dy 25.8 3.2 28.0 29.1 28.1 31.2 23.3 24.4 24.3 25.6 24.7 19.2 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 204 196.7 1.0 0 0 2D-NOESY 85 116.7 1.4 0 0 2D-NOESY (no) 94 47.4 0.5 0 0 JCOUP 3 2.9 1.0 0 0 15N-NOESY-HSQC 19 27.8 1.5 0 0 ORDER 3 1.9 0.6 0 0

As can be seen from these results, the new values for the glycosidic linkage variables are different to those determined in the earlier rounds (which had less data), although they are basically similar. With these structural restraint data, the 131-6 linkages between rings 1 &2 and rings 3&4 prefers a (φ, φ) conformation of (−62.7±8.2°, −112.0±4.1°) with a Gaussian spread of 20.0±4.7°, the β1→3 linkage between rings 5&6 prefers a (φ, φ) conformation of (−50.4±7.7°, −127.4±3.5°) with a Gaussian spread of 15.7±2.8° and while the β1→4 linkages prefers a (φ, φ) conformation of (−82.0±10.6°, −131.4±15.1°) with a Gaussian spread of 18.7±5.1°. The amide groups are not much different to Round 30. The Chi/Res value for the noNOE restraints (2 D-NOESY (no)) is 0.5, which is considerably less than that of the other datasets. This was important since noNOE structural restraints actually represent the lack of observed data, and therefore have less confidence than directly observed structural restraints, and should therefore not be dominating the structure calculations.

Over the next 30 rounds of calculations, the RDC data was included, again first as a base dataset (˜45 restraints) and then the remaining ˜20. The results from the round of structure calculations where all RDCs were included without any being violators, or any of the structural restraints in the other dataset files being violators, were as follows:

Round70 statistics: Ranked run no. Parameter Mean StDev 22 27 16 15 35 24 30 25 1 36 RDC 71.8 3.3 69.1 68.7 71.9 79.0 68.9 71.4 76.2 71.9 68.2 72.7 15N-NOE 26.4 1.4 28.0 24.6 26.3 27.7 25.3 23.9 28.2 26.1 26.7 26.9 2D-NOE 176.3 3.8 177.2 181.2 171.8 174.9 175.6 183.2 177.1 171.0 172.5 178.9 JCOUP 4.4 3.6 0.6 1.9 4.8 0.2 6.4 2.7 2.7 9.9 11.5 3.5 ORDER 4.6 2.7 1.5 2.2 5.0 2.2 6.6 3.9 1.1 8.4 8.9 6.4 VDW 1.8 0.7 1.5 1.5 2.7 1.6 3.0 2.3 2.2 0.5 1.6 1.1 TotChi 285.3 3.8 277.8 280.1 282.5 285.5 285.8 287.3 287.5 287.8 289.4 289.6 1-3_phi −70.4 8.3 −76.1 −73.3 −69.1 −55.5 −78.8 −82.7 −71.7 −69.2 −56.2 −71.6 1-3_psi −114.4 4.3 −107.6 −116.1 −110.4 −115.4 −110.2 −110.9 −119.0 −122.3 −115.5 −116.0 1-3_dyn 21.0 4.1 13.9 22.4 23.4 24.8 14.8 17.3 19.6 25.3 24.4 24.1 a1-3_phi −20.3 9.1 −17.0 −25.6 −12.7 −8.5 −31.6 −35.2 −5.1 −22.8 −23.3 −20.8 a1-3_psi −120.5 3.8 −126.6 −113.4 −126.7 −120.8 −119.8 −118.7 −122.1 −118.3 −119.6 −118.7 a1-3_dyn 16.7 3.4 17.0 14.5 22.1 10.8 12.7 18.4 18.3 17.0 14.9 21.4 1-4_phi −59.4 4.2 −53.9 −59.5 −53.4 −60.5 −60.4 −56.2 −63.2 −67.6 −56.6 −62.9 1-4_psi −152.3 8.5 −150.7 −148.7 −155.5 −167.1 −141.4 −150.8 −166.3 −141.8 −145.5 −155.0 1-4_dyn 19.2 4.9 15.8 16.8 19.5 9.2 27.9 21.8 16.1 18.6 23.0 23.0 HN 119.7 1.1 121.1 119.1 118.0 118.1 118.8 119.5 120.6 120.6 120.0 121.3 HN_dyn 30.7 3.5 36.3 34.2 29.3 33.8 27.2 30.3 33.9 28.5 24.8 29.0 HN_a 119.3 0.9 120.8 118.7 118.8 120.6 120.0 119.3 119.0 119.0 117.6 118.9 HN_a_dy 26.7 4.9 31.1 27.5 25.8 37.0 22.4 30.3 25.9 19.6 21.2 25.9 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 269 283.5 1.1 0 0 2D-NOESY 85 129.6 1.5 0 0 2D-NOESY (no) 94 47.1 0.5 0 0 JCOUP 3 4.4 1.5 0 0 15N-NOESY-HSQC 19 26.2 1.4 0 0 ORDER 3 4.6 1.5 0 0 RDC 65 71.6 1.1 0 0

As can be seen from these results, the new values for the glycosidic linkage variables are only slightly different to those determined in round40. With these structural restraint data, the β1→3 linkages between rings 1 &2 and 3&4 prefers a (φ, φ) conformation of (−70.4±8.3°, −114.4±4.3°) with a Gaussian spread of 21.0±4.1°, the β1→3 linkage between rings 5&6 prefers a (φ, φ) conformation of (−20.3±9.1°, −120.5±16.7°) with a Gaussian spread of 16.7±3.4° and the β1→4 linkage prefers a (φ, φ) conformation of (−59.4±4.2°, −152.3±8.5°) with a Gaussian spread of 19.2±4.9°. The amide groups are again very similar to previous rounds of calculations.

Over the next 5 rounds of calculations, the [¹H, ¹⁵N]-T-ROESY-HSQC data was included as an entire block, since the structural restrains had high confidence of not having mistakes. Inclusion of this dataset revealed a few mistakes in the other dataset files, however. The results from the round of structure calculations where all the ¹⁵N-filtered-ROEs were included without any being violators, or any of the structural restraints in the other dataset files being violators, were as follows:

Round75 statistics: Ranked run no. Parameter Mean StDev 7 4 17 14 3 40 5 24 16 9 RDC 76.1 2.9 70.9 80.5 77.7 73.5 80.0 74.6 77.6 76.1 76.9 73.5 15N-NOE 30.1 0.7 29.7 29.8 30.1 29.7 28.5 31.0 31.3 30.4 30.3 30.4 2D-NOE 179.2 4.6 176.4 171.2 173.9 176.3 180.4 185.8 180.7 182.2 186.1 179.1 15N-ROE 20.2 2.9 17.8 22.2 21.7 22.5 20.2 18.8 19.2 18.0 15.2 26.2 JCOUP 3.6 1.8 6.7 0.6 1.1 4.3 2.4 2.5 5.4 4.0 5.2 3.3 ORDER 3.0 1.7 3.7 4.7 5.4 3.7 0.9 0.6 1.8 5.0 1.9 2.9 VDW 1.4 0.8 2.3 1.8 1.2 1.2 0.8 0.4 0.2 1.6 2.2 2.6 TotChi 313.7 3.4 307.6 310.9 311.1 311.2 313.3 313.6 316.3 317.4 317.8 317.9 1-3_phi −70.7 5.6 −79.6 −80.2 −70.7 −74.3 −64.1 −63.8 −71.6 −70.1 −65.8 −66.8 1-3_psi −122.9 3.7 −122.9 −120.3 −121.9 −124.0 −120.4 −127.1 −123.8 −129.7 −123.8 −115.5 1-3_dyn 21.5 3.9 13.2 19.8 22.1 22.8 24.3 22.6 24.2 28.3 18.1 19.9 a1-3_phi −16.6 4.1 −20.4 −23.8 −13.2 −17.6 −17.5 −12.0 −22.0 −11.9 −12.2 −15.4 a1-3_psi −121.7 2.6 −119.9 −122.1 −120.9 −121.1 −117.3 −124.5 −124.4 −118.9 −121.5 −126.3 a1-3_dyn 18.1 2.1 20.6 14.5 15.0 16.4 18.3 19.6 17.6 17.8 20.9 20.1 1-4_phi −63.6 7.0 −61.4 −66.1 −67.3 −65.3 −77.1 −54.8 −56.1 −71.9 −55.8 −59.9 1-4_psi −147.0 8.8 −139.0 −148.4 −158.8 −143.4 −155.4 −141.6 −127.8 −150.7 −149.9 −154.8 1-4_dyn 19.9 3.2 22.6 19.6 17.2 21.8 14.2 15.8 21.3 19.0 22.4 25.2 HN 119.6 0.9 118.2 119.6 119.5 120.2 120.2 121.7 119.5 118.6 119.3 119.3 HN_dyn 30.5 2.2 32.8 32.1 30.8 28.3 33.6 29.9 26.1 31.5 28.4 31.1 HN_a 119.7 0.7 118.3 119.7 119.2 120.5 119.5 119.1 120.3 120.2 119.3 120.4 HN_a_dy 25.8 2.9 19.2 28.6 30.1 27.9 23.5 26.1 26.4 24.5 25.1 26.3 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 287 312.3 1.1 0 0 2D-NOESY 85 126.7 1.5 0 0 2D-NOESY (no) 94 52.4 0.6 0 0 JCOUP 3 3.6 1.2 0 0 15N-NOESY-HSQC 19 30.2 1.6 0 0 ORDER 3 3.1 1.0 0 0 RDC 65 76.1 1.2 0 0 15N-ROESY-HSQC 18 20.1 1.1 0 0

As can be seen from these results, the new values for the glycosidic linkage variables are very similar to those determined in round70. With these structural restraint data, the β1→3linkages between rings 1&2 and 3&4 prefer a (φ, φ) conformation of (−70.7±5.6°, −122.9±3.7°) with a Gaussian spread of 21.5±3.9°, the β1→3 linkage between rings 5&6 prefers a (φ, φ) conformation of (−16.6±4.1°, −121.7±2.6°) with a Gaussian spread of 18.1±2.1° and the β1→4 linkages prefer a (φ, φ) conformation of (−63.6±7.0°, −147.0±8.8°) with a Gaussian spread of 19.9±3.2°. The amide groups are again very similar to previous rounds of calculations.

Over the next 35 rounds of calculations, the 2D-T-ROESY data was included (there were artefacts in some parts of this spectrum, requiring a lot of rounds of calculations to weed out the anomalous data points), again first as a base dataset (˜40 restraints) of ROE structural restraints and then the remaining ˜20. The results from the round of structure calculations where all ROEs from this dataset were included without any being violators, or any of the structural restraints in the other dataset files being violators, were as follows:

Round110 statistics: Ranked run no. Parameter Mean StDev 40 2 14 20 36 15 13 6 9 30 RDC 73.3 3.1 75.2 76.1 68.8 76.8 69.8 76.0 69.7 74.5 69.7 76.1 15N-NOE 28.9 1.2 28.9 31.3 28.2 30.3 27.4 29.6 27.1 29.4 28.1 28.4 2D-NOE 180.8 4.3 178.8 176.1 187.9 176.0 179.4 175.1 187.1 181.7 183.4 182.8 15N-ROE 20.7 3.3 17.2 16.9 20.0 22.7 28.2 21.9 19.3 19.5 23.3 17.9 2D-ROE 80.2 1.7 77.6 81.3 81.0 77.4 82.4 79.8 80.9 79.3 79.7 82.5 JCOUP 4.6 2.1 3.5 1.1 6.6 7.2 0.5 5.7 5.9 5.0 4.5 5.7 ORDER 3.0 1.9 2.9 7.3 0.7 1.8 5.4 2.9 2.2 4.1 1.8 1.3 VDW 1.9 1.3 1.7 1.4 0.2 1.6 0.8 3.1 2.2 1.3 5.2 1.2 TotChi 393.3 2.8 385.7 391.4 393.5 393.6 393.8 394.1 394.4 394.8 395.7 395.9 1-3_phi −68.8 10.1 −65.6 −68.8 −89.3 −53.7 −78.5 −74.9 −67.6 −55.2 −70.8 −63.2 1-3_psi −120.6 3.7 −120.5 −126.2 −118.4 −116.2 −117.8 −118.0 −121.4 −124.6 −116.4 −126.3 1-3_dyn 20.6 4.5 25.2 26.2 18.5 24.3 11.9 18.0 18.0 24.1 16.0 23.6 a1-3_phi −21.9 8.5 −18.1 −18.6 −38.9 −12.4 −25.4 −20.9 −23.3 −9.3 −18.7 −33.5 a1-3_psi −118.4 3.6 −112.4 −121.3 −121.4 −125.0 −116.2 −115.1 −117.3 −121.9 −116.2 −117.6 a1-3_dyn 17.8 3.7 16.5 14.2 23.6 18.0 15.3 12.5 20.4 22.8 14.4 20.2 1-4_phi −60.4 5.7 −63.1 −60.5 −54.8 −54.1 −60.6 −64.7 −63.0 −73.1 −53.5 −56.9 1-4_psi −146.9 12.9 −157.5 −142.2 −120.5 −150.5 −148.7 −147.6 −155.4 −158.8 −160.6 −126.8 1-4_dyn 21.7 2.4 19.9 22.0 19.4 20.8 20.4 22.5 22.2 20.9 28.1 20.4 HN 119.9 0.7 120.1 118.8 120.8 121.1 118.8 120.1 119.4 119.6 120.0 120.0 HN_dyn 29.7 2.4 28.4 28.2 33.6 28.2 33.7 32.5 29.1 27.3 27.0 28.7 HN_a 119.3 0.9 120.3 119.7 118.5 119.7 118.0 120.2 119.8 118.3 118.4 120.4 HN_a_dy 25.0 2.3 22.9 27.6 24.7 25.2 29.3 22.4 21.5 24.8 26.5 24.6 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 349 391.6 1.1 0 0 2D-NOESY 85 130.6 1.5 0 0 2D-NOESY (no) 94 50.3 0.5 0 0 JCOUP 3 4.6 1.5 0 0 2D-ROESY 62 80.0 1.3 0 0 15N-NOESY-HSQC 19 29.1 1.5 0 0 ORDER 3 3.1 1.0 0 0 RDC 65 73.3 1.1 0 0 15N-ROESY-HSQC 18 20.7 1.1 0 0

As can be seen from these results, the new values for the glycosidic linkage variables are barely different to those determined in round75. With these structural restraint data, the β1→3 linkages between rings 1&2 and 3&4 prefer a (φ, φ) conformation of (−68.8±10.1°, −120.6±3.7°) with a Gaussian spread of 20.6±4.5°, the β1→3 linkage between rings 5&6 prefers a (φ, φ) conformation of (−21.9±8.5°, −118.4±3.6°) with a Gaussian spread of 17.8±3.7° and the β1→4 linkages prefer a (φ, φ) conformation of (−60.4±5.7°, −146.9±12.9°) with a Gaussian spread of 21.7±2.4°. The amide groups are again very similar to previous rounds of calculations.

Over the next 15 rounds of calculations, the noROEs in the 2D-T-ROESY dataset were included. The results from the round of structure calculations where all noROEs were included without any being violators, or any of the structural restraints in the other dataset files being violators, were as follows:

Round125 statistics: Ranked run no. Parameter Mean StDev 14 16 36 28 13 7 33 24 12 40 RDC 75.6 5.1 81.7 69.3 72.3 75.7 75.5 81.1 70.0 84.9 70.5 74.7 15N-NOE 29.6 1.1 29.1 28.1 27.9 31.5 29.8 30.5 29.0 30.6 29.1 29.9 2D-NOE 180.6 4.2 174.2 179.7 176.0 181.1 178.4 185.7 181.7 177.8 182.9 188.9 15N-ROE 19.1 2.6 18.9 20.2 25.1 17.6 16.5 19.9 15.2 21.0 19.0 17.0 2D-ROE 85.8 2.4 81.8 83.0 84.0 85.8 89.1 84.9 86.5 86.2 86.9 89.7 JCOUP 3.5 4.1 0.9 4.0 2.3 1.6 5.9 0.2 14.3 0.3 5.3 0.4 ORDER 5.2 2.9 2.3 6.6 5.8 6.0 7.4 0.9 6.5 1.4 10.7 4.0 VDW 1.0 0.6 0.5 0.9 1.0 1.4 0.5 1.1 1.2 2.4 0.3 0.6 TotChi 400.3 5.8 389.4 391.8 394.4 400.7 403.2 404.5 404.6 404.6 404.7 405.1 1-3_phi −71.6 7.6 −69.0 −70.1 −63.1 −70.5 −72.8 −91.3 −74.5 −62.2 −72.1 −70.0 1-3_psi −124.3 6.1 −137.6 −117.6 −131.6 −126.7 −120.4 −123.9 −124.1 −117.8 −118.7 −124.8 1-3_dyn 21.5 6.0 32.4 15.5 31.3 26.4 16.2 21.6 19.8 17.4 18.5 15.8 a1-3_phi −20.4 9.3 −9.9 −20.4 −15.4 −11.2 −27.8 −38.5 −33.3 −15.3 −19.4 −12.6 a1-3_psi −123.1 2.9 −123.8 −125.6 −116.2 −123.5 −122.6 −124.9 −120.7 −125.7 −126.3 −121.6 a1-3_dyn 17.3 3.0 19.0 22.9 15.5 16.0 14.4 13.8 20.7 13.9 20.3 16.7 1-4_phi −58.0 6.1 −71.0 −48.6 −61.5 −62.3 −61.8 −58.6 −54.8 −55.8 −52.2 −54.0 1-4_psi −142.1 14.5 −164.3 −144.5 −151.5 −158.0 −131.8 −121.5 −129.9 −155.9 −122.2 −141.0 1-4_dyn 18.9 6.6 3.8 22.9 10.6 19.0 22.3 17.6 26.2 22.4 25.6 18.7 HN 119.6 0.9 117.5 119.6 118.6 121.0 120.4 120.3 120.0 119.8 119.2 119.5 HN_dyn 30.9 2.3 32.3 32.1 32.4 29.0 28.5 34.1 27.6 31.8 27.9 33.3 HN_a 119.2 0.8 118.6 119.1 118.9 119.6 119.6 119.7 120.1 117.4 120.0 119.1 HN_a_dy 26.1 3.9 28.6 23.2 25.3 31.3 22.5 26.1 17.6 30.0 26.5 29.4 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 412 399.2 1.0 0 0 2D-NOESY 85 128.7 1.5 0 0 2D-NOESY (no) 94 51.8 0.6 0 0 JCOUP 3 3.6 1.2 0 0 2D-ROESY 62 82.3 1.3 0 0 2D-ROESY (no) 63 3.6 0.1 0 0 15N-NOESY-HSQC 19 29.4 1.5 0 0 ORDER 3 5.1 1.7 0 0 RDC 65 75.6 1.2 0 0 15N-ROESY-HSQC 18 19.1 1.1 0 0

As can be seen from these results, the values for each of the 10 variables, in particular the glycosidic linkage variables and their Gaussian spreads, have not significantly changed since before the inclusion of any 2D-T-ROESY data (either ROEs or noROEs), that is since round75. Since the inclusion of this large body of data (154 structural restraints) did not alter the values for these 10 variables, the dynamic structure was deemed to be solved, and there was no need for further experimental data.

Structure Refinement

The dynamic 3D-solution structure of α-HA₆ was refined using a dynamic-model file (shown below), in which the starting values for the 13 variables were taken from the results of round125 (see above). This allowed the optimisation algorithm to explore this specific χ² _(total) minimum quite effectively, searching for the best possible values of the 13 variables. The ensemble size was increased to 250, 15,000 iteration steps were performed for each run and 100 runs were performed. All seven NMR datasets used in round125 were used in the structure refinement.

remark Dynamic model file for minimisation of alpha-HA6 variables: remark b1-3 linkages rings 1-2 & 3-4 means var 1 fix −70 jump 10.0 start 0.02 var 2 fix −125 jump 10.0 start 0.02 remark b1-3 linkages rings 1-2 & 3-4 Gaussain spread var 3 fix 22 jump 10.0 start 0.3 remark b1-3 linkage rings 5-6 mean var 4 fix −20 jump 10.0 start 0.02 var 5 fix −125 jump 10.0 start 0.02 remark b1-3 linkage rings 5-6 Gaussian spread var 6 fix 18 jump 10.0 start 0.3 remark b1-4 linkages rings 2-3 & 4-5 means var 7 fix −60 jump 10.0 start 0.02 var 8 fix −140 jump 10.0 start 0.02 remark b1-4 linkages rings 2-3 & 4-5 Gaussian spread var 9 fix 19 jump 10.0 start 0.3 remark amides rings 2&4 mean var 10 fix 120 jump 5.0 start 0.3 remark amides rings 2&4 Gaussian spread var 11 fix 30 jump 10.0 start 0.3 remark amide ring 6 mean var 12 fix 120 jump 5.0 start 0.3 remark amide ring 6 Gaussian spread var 13 fix 25 jump 10.0 start 0.3 remark hydroxymethyls rings 2&4&6 mean var 14 fix −60 jump 0.0 start 0.0 var 15 fix 60 jump 0.0 start 0.0 remark hydroxymethyl rings 2&4&6 Gaussian spread var 16 fix 15 jump 0.0 start 0.0 remark methyl groups rings 2&4&6 means var 17 fix −120 jump 0.0 start 0.0 var 18 fix 120 jump 0.0 start 0.0 var 19 fix 0 jump 0.0 start 0.0 remark methyl Gaussian rings 2&4&6 spread var 20 fix 30 jump 0.0 start 0.0 endsection probabilities: remark hydroxymethyl groups rings 2&4&6 bimodal distribution mode 1 2 0.5 0.0 remark methyl groups rings 2&4&6 trimodal distribution mode 2 3 0.33 0.66 0.0 endsection dynamics: remark b1-3 linkages rings 1-2 & 3-4 gyrate 41 1 3 gyrate 42 2 3 gyrate 93 1 3 gyrate 94 2 3 remark b1-3 linkage rings 5-6 gyrate 146 4 6 gyrate 147 5 6 remark b1-4 linkages rings 2-3 & 4-5 gyrate 70 7 9 gyrate 71 8 9 gyrate 122 7 9 gyrate 123 8 9 remark amides rings 2&4 gyrate 31 10 11 gyrate 83 10 11 remark amide ring 6 gyrate 136 12 13 remark hydroxymethyls rings 2&4&6 multigyrate 48 1 14 16 15 16 multigyrate 100 1 14 16 15 16 multigyrate 153 1 14 16 15 16 remark methyl groups rings 2&4&6 multigyrate 35 2 17 20 18 20 19 20 multigyrate 87 2 17 20 18 20 19 20 multigyrate 140 2 17 20 18 20 19 20 endsection

The 20 runs with lowest total χ² _(total) value out of 100 runs in total for this minimisation round were taken for statistical analysis. The values for the best 5 runs are shown here for the sake of brevity, although the mean (Mean) and standard deviation (stDev) values are those calculated from the best 20:

Refinement round statistics: Ranked run no. Parameter Mean StDev 11 5 73 53 98 RDC 71.4 2.2 69.7 72.9 68.5 69.5 68.0 . . . 15N-NOE 29.4 1.0 29.4 29.7 29.4 29.4 29.2 . . . 2D-NOE 178.1 2.6 176.5 179.0 174.2 176.3 178.6 . . . 15N-ROE 19.0 2.4 18.4 16.5 23.3 18.1 19.1 . . . 2D-ROE 84.1 1.5 81.9 82.6 81.9 84.2 84.8 . . . JCOUP 2.7 1.1 2.2 2.1 5.5 2.7 5.1 . . . ORDER 1.7 1.2 3.3 0.5 1.5 5.0 0.2 . . . VDW 1.1 0.4 2.0 1.8 1.1 0.8 1.4 . . . TotChi 387.6 1.6 383.5 385.1 385.4 386.1 386.5 . . . 1-3_phi −69.7 4.1 −73.8 −66.5 −65.6 −72.4 −77.8 . . . 1-3_psi −122.3 1.9 −122.5 −120.2 −119.9 −123.6 −121.4 . . . 1-3_dyn 23.5 2.2 22.7 25.0 25.0 22.9 22.4 . . . a1-3_phi −20.4 2.6 −18.6 −17.4 −17.0 −20.6 −24.3 . . . a1-3_psi −121.8 2.3 −120.1 −121.1 −121.2 −119.8 −121.4 . . . a1-3_dyn 17.5 1.1 16.1 17.6 15.9 16.9 19.3 . . . 1-4_phi −60.4 2.4 −60.6 −58.1 −60.6 −60.7 −63.6 . . . 1-4_psi −142.2 4.7 −146.5 −149.2 −150.5 −144.5 −138.2 . . . 1-4_dyn 19.4 1.3 20.3 17.3 19.0 18.9 20.9 . . . HN 120.4 0.8 121.7 120.5 122.2 120.1 120.0 . . . HN_dyn 29.8 1.4 31.3 30.5 26.9 30.4 29.0 . . . HN_a 119.6 1.0 118.5 118.8 116.9 119.8 120.1 . . . HN_a_dy 25.8 1.0 25.7 26.7 24.6 25.6 24.4 . . . Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 412 386.9 0.9 0 0 2D-NOESY 85 29.2 .5 0 0 2D-NOESY(no) 94 49.3 0.5 0 0 JCOUP 3 2.8 0.9 0 0 2D-ROESY 62 80.8 1.3 0 0 2D-ROESY (no) 63 3.3 0.1 0 0 15N-NOESY-HSQC 19 29.4 1.5 0 0 ORDER 3 1.7 0.6 0 0 RDC 65 71.3 1.1 0 0 15N-ROESY-HSQC 18 19.1 1.1 0 0

No structural restraint has an χ² _(restraint) value greater than 10.0 with these values for the variables, demonstrating the quality of the structure. The final list of all 412 structural restraints with their individual χ² restraint values is given in Appendix A. Therefore, using the optimisation algorithm, the best fit values for the 13 variables describing the dynamic solution structure of α-HA₆ have been determined. Since there are 412 structural restraints, this represents an average of 31.7 structural restraints per degree of freedom defined. The best fit values are: the β1→3 linkages between rings 1&2 and 3&4 have φ and φ angles of −69.7±4.1° (var 1) and −122.3±1.9° (var 2), respectively, with a Gaussian spread of libration of 23.5±2.2° (var 3); the β1→3 linkage between rings 5&6 has φ and φ angles of −20.4±2.6° (var 4) and −121.8±2.3° (var 5), respectively, with a Gaussian spread of libration of 17.5±1.1° (var 6); the β1→4 linkages have φ and φ angles of −60.4±2.4° (var 7) and −142.2±4.7° (var 8), with a Gaussian spread of libration of 19.4±1.3° (var 9). The acetamido groups in rings 2 & 4 have a mean dihedral angle value of 120.4±0.8° (var 10) (i.e., HN and H2 are exactly trans to each other, sine the dihedral is defined on the heavy atoms) with a gaussian spread of 29.8±1.4° (var 11). The acetamido group in ring 6 has a mean value of 119.6±1.0° (var 12) with a gaussian spread of 25.8±1.0° (var 13). The coordinates for the mean solution structure for α-HA₆, generated according to these variables, is given in Appendix A. Several visual representations of the mean structure and dynamic ensemble of structures are given in FIGS. 18-20.

APPENDIX A Hyaluronan Hexasaccharide

Starting 3D-Coordinates for a Hyaluronan Hexasaccharide as a PDB

This is the protein databank (PDB) file format. Column 2 is the atoms number, column 3 the atom type, column 5 the residue number and columns 6-8 are the (x,y,z) Cartesian coordinates of each atomic nucleus.

ATOM 1 C1 BGLA 1 8.160 3.740 −6.827 0.00 0.00 MOLG ATOM 2 H1 BGLA 1 8.574 3.399 −5.860 0.00 0.00 MOLG ATOM 3 C5 BGLA 1 9.716 5.669 −6.880 0.00 0.00 MOLG ATOM 4 H5 BGLA 1 10.140 5.318 −5.935 0.00 0.00 MOLG ATOM 5 O5 BGLA 1 8.279 5.214 −6.937 0.00 0.00 MOLG ATOM 6 C2 BGLA 1 8.929 3.076 −7.999 0.00 0.00 MOLG ATOM 7 H2 BGLA 1 8.489 3.373 −8.954 0.00 0.00 MOLG ATOM 8 O2 BGLA 1 8.794 1.631 −7.841 0.00 0.00 MOLG ATOM 9 HO2 BGLA 1 7.851 1.418 −7.765 0.00 0.00 MOLG ATOM 10 C3 BGLA 1 10.428 3.481 −7.940 0.00 0.00 MOLG ATOM 11 H3 BGLA 1 10.887 3.139 −7.008 0.00 0.00 MOLG ATOM 12 O3 BGLA 1 11.173 2.937 −9.072 0.00 0.00 MOLG ATOM 13 HO3 BGLA 1 11.990 3.449 −9.107 0.00 0.00 MOLG ATOM 14 C4 BGLA 1 10.493 5.025 −8.053 0.00 0.00 MOLG ATOM 15 H4 BGLA 1 10.078 5.364 −9.006 0.00 0.00 MOLG ATOM 16 O4 BGLA 1 11.889 5.426 −7.973 0.00 0.00 MOLG ATOM 17 HO4 BGLA 1 11.893 6.325 −7.577 0.00 0.00 MOLG ATOM 18 C6 BGLA 1 9.950 7.231 −6.916 0.00 0.00 MOLG ATOM 19 O6A BGLA 1 9.481 8.033 −8.095 0.00 0.00 MOLG ATOM 20 O6B BGLA 1 10.641 7.914 −5.772 0.00 0.00 MOLG ATOM 21 C1 BNAG 2 4.120 2.919 −4.124 0.00 0.00 MOLG ATOM 22 H1 BNAG 2 4.797 3.132 −3.275 0.00 0.00 MOLG ATOM 23 C5 BNAG 2 4.228 5.292 −4.758 0.00 0.00 MOLG ATOM 24 H5 BNAG 2 4.879 5.486 −3.900 0.00 0.00 MOLG ATOM 25 O5 BNAG 2 3.336 4.141 −4.431 0.00 0.00 MOLG ATOM 26 C2 BNAG 2 4.990 2.530 −5.355 0.00 0.00 MOLG ATOM 27 H2 BNAG 2 4.333 2.345 −6.209 0.00 0.00 MOLG ATOM 28 N2 BNAG 2 5.726 1.286 −5.066 0.00 0.00 MOLG ATOM 29 H2N BNAG 2 6.406 1.341 −4.312 0.00 0.00 MOLG ATOM 30 C2N BNAG 2 5.542 0.115 −5.720 0.00 0.00 MOLG ATOM 31 O2N BNAG 2 4.736 0.008 −6.632 0.00 0.00 MOLG ATOM 32 CME BNAG 2 6.403 −1.077 −5.257 0.00 0.00 MOLG ATOM 33 H1M BNAG 2 7.443 −0.757 −5.132 0.00 0.00 MOLG ATOM 34 H2M BNAG 2 6.040 −1.469 −4.299 0.00 0.00 MOLG ATOM 35 H3M BNAG 2 6.363 −1.870 −6.011 0.00 0.00 MOLG ATOM 36 C3 BNAG 2 5.953 3.700 −5.681 0.00 0.00 MOLG ATOM 37 H3 BNAG 2 6.614 3.890 −4.830 0.00 0.00 MOLG ATOM 38 O3 BNAG 2 6.739 3.377 −6.907 0.00 0.00 MOLG ATOM 39 C4 BNAG 2 5.096 4.945 −5.992 0.00 0.00 MOLG ATOM 40 H4 BNAG 2 4.464 4.764 −6.867 0.00 0.00 MOLG ATOM 41 O4 BNAG 2 5.958 6.074 −6.259 0.00 0.00 MOLG ATOM 42 HO4 BNAG 2 6.796 5.770 −6.649 0.00 0.00 MOLG ATOM 43 C6 BNAG 2 3.343 6.533 −4.986 0.00 0.00 MOLG ATOM 44 H61 BNAG 2 2.970 6.923 −4.037 0.00 0.00 MOLG ATOM 45 H62 BNAG 2 3.922 7.320 −5.475 0.00 0.00 MOLG ATOM 46 O6 BNAG 2 2.217 6.195 −5.822 0.00 0.00 MOLG ATOM 47 HO6 BNAG 2 2.533 5.645 −6.548 0.00 0.00 MOLG ATOM 48 C1 BGLA 3 0.677 1.330 −0.317 0.00 0.00 MOLG ATOM 49 H1 BGLA 3 0.071 0.554 −0.821 0.00 0.00 MOLG ATOM 50 C5 BGLA 3 2.698 0.706 −1.617 0.00 0.00 MOLG ATOM 51 H5 BGLA 3 2.093 −0.039 −2.143 0.00 0.00 MOLG ATOM 52 O5 BGLA 3 2.100 0.907 −0.248 0.00 0.00 MOLG ATOM 53 C2 BGLA 3 0.592 2.672 −1.095 0.00 0.00 MOLG ATOM 54 H2 BGLA 3 1.148 3.449 −0.563 0.00 0.00 MOLG ATOM 55 O2 BGLA 3 −0.812 3.055 −1.158 0.00 0.00 MOLG ATOM 56 HO2 BGLA 3 −1.156 3.107 −0.252 0.00 0.00 MOLG ATOM 57 C3 BGLA 3 1.153 2.490 −2.530 0.00 0.00 MOLG ATOM 58 H3 BGLA 3 0.572 1.750 −3.087 0.00 0.00 MOLG ATOM 59 O3 BGLA 3 1.176 3.746 −3.280 0.00 0.00 MOLG ATOM 60 HO3 BGLA 3 1.783 3.612 −4.019 0.00 0.00 MOLG ATOM 61 C4 BGLA 3 2.619 2.037 −2.390 0.00 0.00 MOLG ATOM 62 H4 BGLA 3 3.175 2.801 −1.837 0.00 0.00 MOLG ATOM 63 O4 BGLA 3 3.182 1.845 −3.755 0.00 0.00 MOLG ATOM 64 C6 BGLA 3 4.189 0.180 −1.617 0.00 0.00 MOLG ATOM 65 O6A BGLA 3 4.515 −1.152 −2.225 0.00 0.00 MOLG ATOM 66 O6B BGLA 3 5.278 1.013 −1.007 0.00 0.00 MOLG ATOM 67 C1 BNAG 4 −2.161 −0.903 2.896 0.00 0.00 MOLG ATOM 68 H1 BNAG 4 −1.887 −1.813 2.329 0.00 0.00 MOLG ATOM 69 C5 BNAG 4 0.054 −0.923 3.969 0.00 0.00 MOLG ATOM 70 H5 BNAG 4 0.310 −1.831 3.414 0.00 0.00 MOLG ATOM 71 O5 BNAG 4 −1.423 −0.891 4.183 0.00 0.00 MOLG ATOM 72 C2 BNAG 4 −1.762 0.344 2.054 0.00 0.00 MOLG ATOM 73 H2 BNAG 4 −2.012 1.248 2.616 0.00 0.00 MOLG ATOM 74 N2 BNAG 4 −2.542 0.358 0.803 0.00 0.00 MOLG ATOM 75 H2N BNAG 4 −2.303 −0.362 0.125 0.00 0.00 MOLG ATOM 76 C2N BNAG 4 −3.530 1.240 0.516 0.00 0.00 MOLG ATOM 77 O2N BNAG 4 −3.843 2.131 1.290 0.00 0.00 MOLG ATOM 78 CME BNAG 4 −4.241 1.060 −0.840 0.00 0.00 MOLG ATOM 79 H1M BNAG 4 −5.007 0.280 −0.756 0.00 0.00 MOLG ATOM 80 H2M BNAG 4 −4.725 1.992 −1.153 0.00 0.00 MOLG ATOM 81 H3M BNAG 4 −3.510 0.760 −1.597 0.00 0.00 MOLG ATOM 82 C3 BNAG 4 −0.235 0.306 1.779 0.00 0.00 MOLG ATOM 83 H3 BNAG 4 0.025 −0.592 1.208 0.00 0.00 MOLG ATOM 84 O3 BNAG 4 0.179 1.539 1.050 0.00 0.00 MOLG ATOM 85 C4 BNAG 4 0.483 0.317 3.146 0.00 0.00 MOLG ATOM 86 H4 BNAG 4 0.244 1.235 3.690 0.00 0.00 MOLG ATOM 87 O4 BNAG 4 1.914 0.255 2.940 0.00 0.00 MOLG ATOM 88 HO4 BNAG 4 2.132 0.692 2.098 0.00 0.00 MOLG ATOM 89 C6 BNAG 4 0.757 −0.974 5.342 0.00 0.00 MOLG ATOM 90 H61 BNAG 4 0.406 −1.833 5.919 0.00 0.00 MOLG ATOM 91 H62 BNAG 4 1.836 −1.073 5.210 0.00 0.00 MOLG ATOM 92 O6 BNAG 4 0.485 0.219 6.106 0.00 0.00 MOLG ATOM 93 HO6 BNAG 4 0.916 0.151 6.960 0.00 0.00 MOLG ATOM 94 C1 BGLA 5 −6.107 −3.901 4.931 0.00 0.00 MOLG ATOM 95 H1 BGLA 5 −6.799 −3.126 5.312 0.00 0.00 MOLG ATOM 96 C5 BGLA 5 −5.501 −2.467 3.001 0.00 0.00 MOLG ATOM 97 H5 BGLA 5 −6.166 −1.696 3.402 0.00 0.00 MOLG ATOM 98 O5 BGLA 5 −6.021 −3.810 3.453 0.00 0.00 MOLG ATOM 99 C2 BGLA 5 −4.696 −3.693 5.532 0.00 0.00 MOLG ATOM 100 H2 BGLA 5 −4.020 −4.481 5.188 0.00 0.00 MOLG ATOM 101 O2 BGLA 5 −4.776 −3.743 6.989 0.00 0.00 MOLG ATOM 102 HO2 BGLA 5 −3.931 −3.393 7.298 0.00 0.00 MOLG ATOM 103 C3 BGLA 5 −4.149 −2.303 5.131 0.00 0.00 MOLG ATOM 104 H3 BGLA 5 −4.795 −1.505 5.511 0.00 0.00 MOLG ATOM 105 O3 BGLA 5 −2.803 −2.127 5.671 0.00 0.00 MOLG ATOM 106 HO3 BGLA 5 −2.318 −1.516 5.095 0.00 0.00 MOLG ATOM 107 C4 BGLA 5 −4.091 −2.259 3.593 0.00 0.00 MOLG ATOM 108 H4 BGLA 5 −3.425 −3.050 3.232 0.00 0.00 MOLG ATOM 109 O4 BGLA 5 −3.602 −0.916 3.196 0.00 0.00 MOLG ATOM 110 C6 BGLA 5 −5.446 −2.274 1.435 0.00 0.00 MOLG ATOM 111 O6A BGLA 5 −6.232 −1.175 0.786 0.00 0.00 MOLG ATOM 112 O6B BGLA 5 −4.607 −3.192 0.595 0.00 0.00 MOLG ATOM 113 C1 ANAG 6 −9.771 −5.639 7.394 0.00 0.00 MOLG ATOM 114 H1 ANAG 6 −9.902 −5.840 8.472 0.00 0.00 MOLG ATOM 115 O1 ANAG 6 −10.531 −4.478 7.072 0.00 0.00 MOLG ATOM 116 HO1 ANAG 6 −11.413 −4.826 6.920 0.00 0.00 MOLG ATOM 117 C5 ANAG 6 −10.162 −6.634 5.164 0.00 0.00 MOLG ATOM 118 H5 ANAG 6 −10.663 −5.719 4.836 0.00 0.00 MOLG ATOM 119 O5 ANAG 6 −10.333 −6.791 6.655 0.00 0.00 MOLG ATOM 120 C2 ANAG 6 −8.249 −5.521 7.079 0.00 0.00 MOLG ATOM 121 H2 ANAG 6 −7.758 −6.450 7.380 0.00 0.00 MOLG ATOM 122 N2 ANAG 6 −7.560 −4.441 7.822 0.00 0.00 MOLG ATOM 123 H2N ANAG 6 −8.004 −3.534 7.767 0.00 0.00 MOLG ATOM 124 C2N ANAG 6 −6.412 −4.597 8.534 0.00 0.00 MOLG ATOM 125 O2N ANAG 6 −5.842 −5.671 8.624 0.00 0.00 MOLG ATOM 126 CME ANAG 6 −5.874 −3.328 9.223 0.00 0.00 MOLG ATOM 127 H1M ANAG 6 −6.237 −2.437 8.698 0.00 0.00 MOLG ATOM 128 H2M ANAG 6 −6.216 −3.298 10.264 0.00 0.00 MOLG ATOM 129 H3M ANAG 6 −4.778 −3.325 9.210 0.00 0.00 MOLG ATOM 130 C3 ANAG 6 −8.046 −5.311 5.562 0.00 0.00 MOLG ATOM 131 H3 ANAG 6 −8.544 −4.389 5.249 0.00 0.00 MOLG ATOM 132 O3 ANAG 6 −6.591 −5.245 5.283 0.00 0.00 MOLG ATOM 133 C4 ANAG 6 −8.649 −6.529 4.836 0.00 0.00 MOLG ATOM 134 H4 ANAG 6 −8.132 −7.442 5.141 0.00 0.00 MOLG ATOM 135 O4 ANAG 6 −8.479 −6.353 3.408 0.00 0.00 MOLG ATOM 136 HO4 ANAG 6 −7.576 −6.045 3.230 0.00 0.00 MOLG ATOM 137 C6 ANAG 6 −10.826 −7.824 4.440 0.00 0.00 MOLG ATOM 138 H61 ANAG 6 −11.860 −7.946 4.769 0.00 0.00 MOLG ATOM 139 H62 ANAG 6 −10.833 −7.653 3.361 0.00 0.00 MOLG ATOM 140 O6 ANAG 6 −10.122 −9.053 4.721 0.00 0.00 MOLG ATOM 141 HO6 ANAG 6 −10.547 −9.771 4.246 0.00 0.00 MOLG END

Internal Coordinate Table for a Hyaluronan Hexasaccharide

The first column specifies the internal coordinate number, the next eight columns represent the atoms definitions. The next five column specify a distance (ij), angle (ijk), dihedral (ijkl), angle (jkl) and distance (kl). An asterisk in column 7 means that the atoms are in a fixed geometry with respect to other atoms (usually specifying fixed geometry due to hybridisation, e.g., sp², sp³) and the angles are used in a slightly different manner, but these angles are not subject to variation during optimisation.

1 2 O3 1 C1 1 O5 1 C5 1.46881 108.618 −179.317 111.931 1.50839 2 2 O3 1 O5 1 *C1 1 C2 1.46881 108.618 119.308 109.25 1.55108 3 2 O3 1 O5 1 *C1 1 H1 1.46881 108.618 −119.795 109.959 1.10579 4 1 C4 1 C5 1 O5 1 C1 1.54738 108.916 60.0395 111.931 1.48288 5 1 C4 1 O5 1 *C5 1 C6 1.54738 108.916 122.915 116.007 1.57984 6 1 C4 1 O5 1 *C5 1 H5 1.54738 108.916 −118.201 107.77 1.09362 7 1 O5 1 C1 1 C2 1 O2 1.48288 109.25 179.474 107.224 1.45987 8 1 O2 1 C1 1 *C2 1 C3 1.45987 107.224 −119.538 109.756 1.55387 9 1 O2 1 C1 1 *C2 1 H2 1.45987 107.224 118.538 110.146 1.09263 10 1 C1 1 C2 1 O2 1 HO2 1.55108 107.224 53.3625 108.41 0.969739 11 1 C1 1 C2 1 C3 1 O3 1.55108 109.756 −176.756 111.447 1.46027 12 1 O3 1 C2 1 *C3 1 C4 1.46027 111.447 116.898 107.302 1.54949 13 1 O3 1 C2 1 *C3 1 H3 1.46027 111.447 −121.927 110.836 1.09374 14 1 C2 1 C3 1 O3 1 HO3 1.55387 111.447 162.78 105.215 0.96481 15 1 O5 1 C5 1 C4 1 C3 1.50839 108.916 −59.823 109.777 1.54949 16 1 C3 1 C5 1 *C4 1 O4 1.54949 109.777 −118.244 108.994 1.45465 17 1 C3 1 C5 1 *C4 1 H4 1.54949 109.777 122.251 109.945 1.09332 18 1 C2 1 C3 1 C4 1 C5 1.55387 107.302 60.1054 109.777 1.54738 19 1 C5 1 C4 1 O4 1 HO4 1.54738 108.994 −31.4217 106.162 0.982361 20 1 O5 1 C5 1 C6 1 O6A 1.50839 116.007 −60.3259 119.992 1.50107 21 1 O6A 1 C5 1 *C6 1 O6B 1.50107 119.992 179.997 120.049 1.5009 22 3 O4 2 C1 2 O5 2 C5 1.47292 108.411 177.566 111.385 1.49245 23 3 O4 2 O5 2 *C1 2 C2 1.47292 108.411 122.382 109.72 1.55679 24 3 O4 2 O5 2 *C1 2 H1 1.47292 108.411 −119.339 108.871 1.10657 25 2 C4 2 C5 2 O5 2 C1 1.54809 109.688 59.9715 111.385 1.48398 26 2 C4 2 O5 2 *C5 2 C6 1.54809 109.688 123.117 108.072 1.5412 27 2 C4 2 O5 2 *C5 2 H5 1.54809 109.688 −119.495 108.692 1.09435 28 2 O5 2 C1 2 C2 2 N2 1.48398 109.72 −177.748 109.566 1.47403 29 2 N2 2 C1 2 *C2 2 C3 1.47403 109.566 −122.352 108.959 1.55001 30 2 N2 2 C1 2 *C2 2 H2 1.47403 109.566 118.034 108.913 1.09325 31 2 C1 2 C2 2 N2 2 C2N 1.55679 109.566 115.346 124.57 1.35381 32 2 C2N 2 C2 2 *N2 2 H2N 1.35381 124.57 −179.409 115.699 1.01683 33 2 C2 2 N2 2 C2N 2 CME 1.47403 124.57 −179.405 116.603 1.54161 34 2 CME 2 N2 2 *C2N 2 O2N 1.54161 116.603 −179.909 121.735 1.22181 35 2 N2 2 C2N 2 CME 2 H1M 1.35381 116.603 −45.6045 109.797 1.09527 36 2 H1M 2 C2N 2 *CME 2 H2M 1.09527 109.797 119.908 110.72 1.0969 37 2 H1M 2 C2N 2 *CME 2 H3M 1.09527 109.797 −119.549 109.437 1.09497 38 2 C1 2 C2 2 C3 2 O3 1.55679 108.959 −176.706 109.681 1.49171 39 2 O3 2 C2 2 *C3 2 C4 1.49171 109.681 116.853 107.839 1.54311 40 2 O3 2 C2 2 *C3 2 H3 1.49171 109.681 −122.4 110.049 1.09418 41 1 O5 1 C1 2 O3 2 C3 1.48288 108.618 −73.6356 114.298 1.49171 42 2 C2 2 C3 2 O3 1 C1 1.55001 109.681 −137.983 114.298 1.46881 43 2 O5 2 C5 2 C4 2 C3 1.49245 109.688 −59.8491 109.365 1.54311 44 2 C3 2 C5 2 *C4 2 O4 1.54311 109.365 −119.185 107.852 1.44533 45 2 C3 2 C5 2 *C4 2 H4 1.54311 109.365 121.728 110.523 1.09445 46 2 O3 2 C3 2 C4 2 C5 1.49171 107.559 178.271 109.365 1.54809 47 2 C5 2 C4 2 O4 2 HO4 1.54809 107.852 149.107 110.099 0.973016 48 2 O5 2 C5 2 C6 2 O6 1.49245 108.072 −45.3199 110.199 1.44257 49 2 O6 2 C5 2 *C6 2 H61 1.44257 110.199 120.363 110.809 1.09171 50 2 O6 2 C5 2 *C6 2 H62 1.44257 110.199 −120.01 109.994 1.09258 51 2 C5 2 C6 2 O6 2 HO6 1.5412 110.199 −43.6484 108.315 0.964071 52 4 O3 3 C1 3 O5 3 C5 1.46982 108.767 −178.507 112.064 1.50737 53 4 O3 3 O5 3 *C1 3 C2 1.46982 108.767 118.502 108.754 1.55354 54 4 O3 3 O5 3 *C1 3 H1 1.46982 108.767 −120.379 110.247 1.10609 55 3 C4 3 C5 3 O5 3 C1 1.54121 108.664 60.0468 112.064 1.48614 56 3 C4 3 O5 3 *C5 3 C6 1.54121 108.664 123.074 114.739 1.58106 57 3 C4 3 O5 3 *C5 3 H5 1.54121 108.664 −117.561 107.937 1.09441 58 3 O5 3 C1 3 C2 3 O2 1.48614 108.754 179.466 107.549 1.45667 59 3 O2 3 C1 3 *C2 3 C3 1.45667 107.549 −119.597 110.004 1.55147 60 3 O2 3 C1 3 *C2 3 H2 1.45667 107.549 118.502 110.019 1.09357 61 3 C1 3 C2 3 O2 3 HO2 1.55354 107.549 56.6882 108.382 0.970503 62 3 C1 3 C2 3 C3 3 O3 1.55354 110.004 −176.337 112.279 1.46307 63 3 O3 3 C2 3 *C3 3 C4 1.46307 112.279 116.579 107.127 1.54077 64 3 O3 3 C2 3 *C3 3 H3 1.46307 112.279 −122.498 111.005 1.09335 65 3 C2 3 C3 3 O3 3 HO3 1.55147 112.279 162.001 106.442 0.965674 66 3 O5 3 C5 3 C4 3 O4 1.50737 108.664 −178.871 109.211 1.48898 67 3 O4 3 C5 3 *C4 3 C3 1.48898 109.211 118.986 110.38 1.54077 68 3 O4 3 C5 3 *C4 3 H4 1.48898 109.211 −121.536 108.861 1.09482 69 3 C2 3 C3 3 C4 3 O4 1.55147 107.127 179.621 108.323 1.48898 70 2 O5 2 C1 3 O4 3 C4 1.48398 108.411 −74.4818 112.113 1.48898 71 3 C5 3 C4 3 O4 2 C1 1.54121 109.211 −133.198 112.113 1.47292 72 3 O5 3 C5 3 C6 3 O6A 1.50737 114.739 117.52 120.024 1.50005 73 3 O6A 3 C5 3 *C6 3 O6B 1.50005 120.024 −179.926 119.979 1.50064 74 5 O4 4 C1 4 O5 4 C5 1.47195 108.074 178.115 111.57 1.49277 75 5 O4 4 O5 4 *C1 4 C2 1.47195 108.074 121.821 109.587 1.55665 76 5 O4 4 O5 4 *C1 4 H1 1.47195 108.074 −119.431 109.144 1.10665 77 4 C4 4 C5 4 O5 4 C1 1.54886 109.455 59.9473 111.57 1.48363 78 4 C4 4 O5 4 *C5 4 C6 1.54886 109.455 122.618 108.897 1.54335 79 4 C4 4 O5 4 *C5 4 H5 1.54886 109.455 −119.319 108.777 1.09454 80 4 O5 4 C1 4 C2 4 N2 1.48363 109.587 −177.533 109.328 1.47431 81 4 N2 4 C1 4 *C2 4 C3 1.47431 109.328 −122.516 109.172 1.55203 82 4 N2 4 C1 4 *C2 4 H2 1.47431 109.328 117.728 109.007 1.09342 83 4 C1 4 C2 4 N2 4 C2N 1.55665 109.328 109.611 124.862 1.35515 84 4 C2N 4 C2 4 *N2 4 H2N 1.35515 124.862 −179.66 115.75 1.01745 85 4 C2 4 N2 4 C2N 4 CME 1.47431 124.862 −178.74 116.522 1.54164 86 4 CME 4 N2 4 *C2N 4 O2N 1.54164 116.522 179.951 121.842 1.22103 87 4 N2 4 C2N 4 CME 4 H1M 1.35515 116.522 81.7555 109.747 1.09645 88 4 H1M 4 C2N 4 *CME 4 H2M 1.09645 109.747 119.901 110.832 1.09583 89 4 H1M 4 C2N 4 *CME 4 H3M 1.09645 109.747 −119.49 109.415 1.09426 90 4 C1 4 C2 4 C3 4 O3 1.55665 109.172 −176.309 109.851 1.49102 91 4 O3 4 C2 4 *C3 4 C4 1.49102 109.851 116.469 107.485 1.54413 92 4 O3 4 C2 4 *C3 4 H3 1.49102 109.851 −122.334 110.239 1.09547 93 3 O5 3 C1 4 O3 4 C3 1.48614 108.767 −81.1834 115.545 1.49102 94 4 C2 4 C3 4 O3 3 C1 1.55203 109.851 −114.743 115.545 1.46982 95 4 O5 4 C5 4 C4 4 C3 1.49277 109.455 −59.9379 109.628 1.54413 96 4 C3 4 C5 4 *C4 4 O4 1.54413 109.628 −119.443 108.375 1.44708 97 4 C3 4 C5 4 *C4 4 H4 1.54413 109.628 121.491 110.317 1.09352 98 4 O3 4 C3 4 C4 4 C5 1.49102 107.328 178.203 109.628 1.54886 99 4 C5 4 C4 4 O4 4 HO4 1.54886 108.375 150.177 108.989 0.973374 100 4 O5 4 C5 4 C6 4 O6 1.49277 108.897 −63.3575 110.974 1.44254 101 4 O6 4 C5 4 *C6 4 H61 1.44254 110.974 119.813 110.452 1.09271 102 4 O6 4 C5 4 *C6 4 H62 1.44254 110.974 −120.841 110.223 1.09154 103 4 C5 4 C6 4 O6 4 HO6 1.54335 110.974 178.675 109.162 0.95901 104 6 O3 5 C1 5 O5 5 C5 1.47122 108.272 −178.739 111.897 1.50942 105 6 O3 5 O5 5 *C1 5 C2 1.47122 108.272 118.759 109.016 1.5477 106 6 O3 5 O5 5 *C1 5 H1 1.47122 108.272 −120.742 109.655 1.10664 107 5 C4 5 C5 5 O5 5 C1 1.54332 108.65 59.9488 111.897 1.48329 108 5 C4 5 O5 5 *C5 5 C6 1.54332 108.65 122.757 114.695 1.57881 109 5 C4 5 O5 5 *C5 5 H5 1.54332 108.65 −117.633 107.927 1.09429 110 5 O5 5 C1 5 C2 5 O2 1.48329 109.016 178.406 109.448 1.46005 111 5 O2 5 C1 5 *C2 5 C3 1.46005 109.448 −118.516 110.031 1.54664 112 5 O2 5 C1 5 *C2 5 H2 1.46005 109.448 119.638 110.152 1.09373 113 5 C1 5 C2 5 O2 5 HO2 1.5477 109.448 −166.271 105.013 0.965405 114 5 C1 5 C2 5 C3 5 O3 1.5477 110.031 −178.488 109.772 1.46092 115 5 O3 5 C2 5 *C3 5 C4 1.46092 109.772 118.736 107.337 1.53972 116 5 O3 5 C2 5 *C3 5 H3 1.46092 109.772 −120.641 110.88 1.09477 117 5 C2 5 C3 5 O3 5 HO3 1.54664 109.772 152.259 108.491 0.969702 118 5 O5 5 C5 5 C4 5 O4 1.50942 108.65 −177.676 108.695 1.48337 119 5 O4 5 C5 5 *C4 5 C3 1.48337 108.695 117.91 110.175 1.53972 120 5 O4 5 C5 5 *C4 5 H4 1.48337 108.695 −121.851 109.377 1.09524 121 5 C2 5 C3 5 C4 5 O4 1.54664 107.337 178.496 107.796 1.48337 122 4 O5 4 C1 5 O4 5 C4 1.48363 108.074 −78.1341 112.66 1.48337 123 5 C5 5 C4 5 O4 4 C1 1.54332 108.695 −142.547 112.66 1.47195 124 5 O5 5 C5 5 C6 5 O6A 1.50942 114.695 119.91 120.055 1.49893 125 5 O6A 5 C5 5 *C6 5 O6B 1.49893 120.055 −179.956 119.992 1.50075 126 6 O5 6 C1 6 O1 6 HO1 1.47955 108.604 31.8202 103.324 0.960277 127 6 O5 6 O1 6 *C1 6 C2 1.47955 108.604 122.28 114.429 1.55873 128 6 O5 6 O1 6 *C1 6 H1 1.47955 108.604 −116.193 107.8 1.10438 129 6 O1 6 C1 6 O5 6 C5 1.4245 108.604 65.4749 111.683 1.50896 130 6 C4 6 C5 6 O5 6 C1 1.5517 109.05 60.0827 111.683 1.47955 131 6 C4 6 O5 6 *C5 6 C6 1.5517 109.05 122.744 109.548 1.5431 132 6 C4 6 O5 6 *C5 6 H5 1.5517 109.05 −119.188 109.361 1.09353 133 6 O5 6 C1 6 C2 6 N2 1.47955 109.202 −176.931 114.086 1.48094 134 6 N2 6 C1 6 *C2 6 C3 1.48094 114.086 −123.144 109.697 1.54486 135 6 N2 6 C1 6 *C2 6 H2 1.48094 114.086 117.734 108.58 1.09303 136 6 C1 6 C2 6 N2 6 C2N 1.55873 114.086 129.507 124.876 1.35985 137 6 C2N 6 C2 6 *N2 6 H2N 1.35985 124.876 179.625 114.992 1.01134 138 6 C2 6 N2 6 C2N 6 CME 1.48094 124.876 179.809 115.746 1.54095 139 6 CME 6 N2 6 *C2N 6 O2N 1.54095 115.746 179.986 122.302 1.21921 140 6 N2 6 C2N 6 CME 6 H1M 1.35985 115.746 −24.4507 109.856 1.09603 141 6 H1M 6 C2N 6 *CME 6 H2M 1.09603 109.856 120.123 109.77 1.09615 142 6 H1M 6 C2N 6 *CME 6 H3M 1.09603 109.856 −119.969 110.247 1.09608 143 6 C1 6 C2 6 C3 6 O3 1.55873 109.697 −178.228 108.646 1.48298 144 6 O3 6 C2 6 *C3 6 C4 1.48298 108.646 118.275 107.686 1.54085 145 6 O3 6 C2 6 *C3 6 H3 1.48298 108.646 −121.232 109.621 1.09364 146 5 O5 5 C1 6 O3 6 C3 1.48329 108.272 −97.8928 114.107 1.48298 147 6 C2 6 C3 6 O3 5 C1 1.54486 108.646 −108.314 114.107 1.47122 148 6 O5 6 C5 6 C4 6 C3 1.50896 109.05 −59.759 109.601 1.54085 149 6 C3 6 C5 6 *C4 6 O4 1.54085 109.601 −119.186 109.328 1.44881 150 6 C3 6 C5 6 *C4 6 H4 1.54085 109.601 121.346 110.231 1.09265 151 6 O3 6 C3 6 C4 6 C5 1.48298 109.299 177.998 109.601 1.5517 152 6 C5 6 C4 6 O4 6 HO4 1.5517 109.328 164.466 109.177 0.970545 153 6 O5 6 C5 6 C6 6 O6 1.50896 109.548 −66.9804 110.81 1.44396 154 6 O6 6 C5 6 *C6 6 H61 1.44396 110.81 119.674 110.626 1.09192 155 6 O6 6 C5 6 *C6 6 H62 1.44396 110.81 −120.96 110.209 1.09249 156 6 C5 6 C6 6 O6 6 HO6 1.5431 110.81 −178.992 108.93 0.960091

[¹H-¹H]-NOESY Dataset for a Hyaluronan Hexasaccharide

remark 2D-NOESY data for alpha-HA6 configuration: field 900 solvent h2o temp 298 visc 0.88 ident 2D-NOESY mix_time 400 ms endsection data: remark NOE no. ring ring donor ring ring acc int error code asgn 1 a 6 H1M a 6 H2N 4.75 1.90 0 ovlp 1 a 6 H2M a 6 H2N 4.75 1.90 0 ovlp 1 a 6 H3M a 6 H2N 4.75 1.90 0 asgn 2 a 6 H1 a 6 H2N 1.37 0.55 0 asgn 3 a 6 H2N a 6 H2N 110.02 44.01 0 asgn 4 a 6 H3 a 6 H2N 2.10 0.84 0 asgn 5 a 6 H4 a 6 H2N 0.09 0.05 0 asgn 6 a′ 5 H1 a 6 H2N 2.57 1.03 0 asgn 7 a′ 5 H2 a 6 H2N 0.09 0.05 0 asgn 8 a′ 5 H3 a 6 H2N 0.14 0.07 0 asgn 9 a′ 5 H5 a 6 H2N 0.31 0.13 0 asgn 10 a 6 H1 a 6 H1 421.59 168.63 0 asgn 11 a 6 H3 a 6 H1 1.41 0.56 0 asgn 12 a 6 H4 a 6 H1 0.69 0.28 0 asgn 13 a 6 H5 a 6 H1 0.72 0.29 0 asgn 14 a 6 H1 a 6 H2 12.46 5.02 0 asgn 15 a 6 H2 a 6 H2 303.23 122.37 0 asgn 16 a 6 H4 a 6 H2 3.19 1.30 0 asgn 17 a′ 5 H1 a 6 H2 1.56 0.64 0 asgn 301 a 6 H1M a 6 H1M 1284.96 513.98 6 ovlp 301 a 6 H2M a 6 H1M 1284.96 513.98 6 ovlp 301 a 6 H3M a 6 H1M 1284.96 513.98 6 ovlp 301 a 6 H1M a 6 H2M 1284.96 513.98 6 ovlp 301 a 6 H2M a 6 H2M 1284.96 513.98 6 ovlp 301 a 6 H3M a 6 H2M 1284.96 513.98 6 ovlp 301 a 6 H1M a 6 H3M 1284.96 513.98 6 ovlp 301 a 6 H2M a 6 H3M 1284.96 513.98 6 ovlp 301 a 6 H3M a 6 H3M 1284.96 513.98 6 asgn 18 a′ 5 H1 a′ 5 H1 283.02 113.22 0 asgn 19 a′ 5 H3 a′ 5 H1 6.48 2.59 0 asgn 20 a′ 5 H4 a′ 5 H1 2.00 0.80 0 asgn 21 a′ 5 H5 a′ 5 H1 21.03 8.41 0 asgn 22 a 6 H2 a′ 5 H1 0.85 0.34 0 asgn 23 a 6 H3 a′ 5 H1 10.22 4.09 0 asgn 24 a 6 H1M a′ 5 H1 0.66 0.27 0 ovlp 24 a 6 H2M a′ 5 H1 0.66 0.27 0 ovlp 24 a 6 H3M a′ 5 H1 0.66 0.27 0 asgn 25 a′ 5 H2 a′ 5 H2 272.87 109.21 0 asgn 26 a′ 5 H4 a′ 5 H2 10.10 4.04 0 asgn 27 a 6 H3 a′ 5 H2 1.32 0.53 0 asgn 28 g 4 H1 a′ 5 H2 1.20 0.48 0 asgn 29 f′ 3 H1 f′ 3 H1 311.90 124.76 0 asgn 30 f′ 3 H3 f′ 3 H1 9.81 3.92 0 asgn 31 g 4 H1M f′ 3 H1 1.09 0.44 0 ovlp 31 g 4 H2M f′ 3 H1 1.09 0.44 0 ovlp 31 g 4 H3M f′ 3 H1 1.09 0.44 0 asgn 32 g 4 H2 f′ 3 H1 0.91 0.37 0 asgn 33 g 4 H3 f′ 3 H1 25.86 10.34 0 ovlp 33 f′ 3 H5 f 3 H1 25.86 10.34 0 asgn 34 f′ 3 H1 g 4 H4 0.80 0.32 0 asgn 35 f′ 3 H2 f′ 3 H2 268.44 107.59 0 asgn 36 f′ 3 H4 f′ 3 H2 8.79 3.52 0 asgn 37 w 2 H1 f′ 3 H2 0.91 0.37 0 asgn 38 g 4 H1M g 4 H2N 9.42 3.77 0 ovlp 38 g 4 H2M g 4 H2N 9.42 3.77 0 ovlp 38 g 4 H3M g 4 H2N 9.42 3.77 0 asgn 39 g 4 H1 g 4 H2N 3.70 1.48 0 asgn 40 g 4 H2N g 4 H2N 185.95 74.38 0 asgn 41 g 4 H3 g 4 H2N 5.84 2.34 0 ovlp 41 a′ 5 H5 g 4 H2N 5.84 2.34 0 ovlp 41 f′ 3 H5 g 4 H2N 5.84 2.34 0 asgn 42 g 4 H4 g 4 H2N 0.22 0.09 0 asgn 43 g 4 H5 g 4 H2N 0.40 0.16 0 asgn 44 f′ 3 H1 g 4 H2N 4.86 1.94 0 asgn 45 f′ 3 H2 g 4 H2H 0.19 0.08 0 asgn 46 f′ 3 H3 g 4 H2N 0.33 0.13 0 asgn 47 g 4 H1 g 4 H1 218.09 87.24 0 asgn 48 g 4 H2N g 4 H1 4.71 1.88 0 asgn 49 g 4 H3 g 4 H1 12.75 5.10 0 ovlp 49 a′ 5 H5 g 4 H1 12.75 5.10 0 asgn 50 g 4 H5 g 4 H1 9.57 3.83 0 asgn 51 a′ 5 H4 g 4 H1 17.14 6.85 0 asgn 52 a′ 5 H2 g 4 H1 0.71 0.28 0 asgn 53 g 4 H1M g 4 H1 0.37 0.15 0 ovlp 53 g 4 H2M g 4 H1 0.37 0.15 0 ovlp 53 g 4 H3M g 4 H1 0.37 0.15 0 asgn 54 g 4 H1 a′ 5 H3 0.71 0.28 0 asgn 55 g 4 H1M f′ 3 H3 0.91 0.37 0 ovlp 55 g 4 H2M f′ 3 H3 0.91 0.37 0 ovlp 55 g 4 H3M f′ 3 H3 0.91 0.37 0 asgn 56 g 4 H1M g 4 H2 1.03 0.41 0 ovlp 56 g 4 H2M g 4 H2 1.03 0.41 0 ovlp 56 g 4 H3M g 4 H2 1.03 0.41 0 asgn 302 g 4 H1M g 4 H1M 1206.25 482.50 6 ovlp 302 g 4 H2M g 4 H1M 1206.25 482.50 6 ovlp 302 g 4 H3M g 4 H1M 1206.25 482.50 6 ovlp 302 g 4 H1M g 4 H2M 1206.25 482.50 6 ovlp 302 g 4 H2M g 4 H2M 1206.25 482.50 6 ovlp 302 g 4 H3M g 4 H2M 1206.25 482.50 6 ovlp 302 g 4 H1M g 4 H3M 1206.25 482.50 6 ovlp 302 g 4 H2M g 4 H3M 1206.25 482.50 6 ovlp 302 g 4 H3M g 4 H3M 1206.25 482.50 6 asgn 57 w 2 H1M w 2 H2N 8.91 3.56 0 ovlp 57 w 2 H2M w 2 H2N 8.91 3.56 0 ovlp 57 w 2 H3M w 2 H2N 8.91 3.56 0 asgn 58 w 2 H1 w 2 H2N 3.73 1.49 0 asgn 59 w 2 H2N w 2 H2N 249.70 99.88 0 asgn 60 w 2 H3 w 2 H2N 6.44 2.58 0 ovlp 60 w′ 1 H5 w 2 H2N 6.44 2.58 0 ovlp 60 f′ 3 H5 w 2 H2N 6.44 2.58 0 asgn 61 w 2 H4 w 2 H2N 0.21 0.09 0 asgn 62 w 2 H5 w 2 H2N 0.45 0.18 0 asgn 63 w′ 1 H1 w 2 H2N 5.94 2.38 0 asgn 64 w′ 1 H2 w 2 H2N 0.20 0.08 0 asgn 65 w′ 1 H3 w 2 H2N 0.34 0.14 0 asgn 66 w 2 H1 w 2 H1 259.20 103.68 0 asgn 67 w 2 H3 w 2 H1 13.51 5.40 0 ovlp 67 f′ 3 H5 w 2 H1 13.51 5.40 0 asgn 68 w 2 H5 w 2 H1 11.58 4.63 0 asgn 69 f′ 3 H4 w 2 H1 15.61 6.24 0 asgn 70 f′ 3 H2 w 2 H1 0.51 0.20 0 asgn 71 w 2 H1M w 2 H1 0.27 0.11 0 ovlp 71 w 2 H2M w 2 H1 0.27 0.11 0 ovlp 71 w 2 H3M w 2 H1 0.27 0.11 0 asgn 72 w 2 H1M w 2 H2 1.04 0.42 0 ovlp 72 w 2 H2M w 2 H2 1.04 0.42 0 ovlp 72 w 2 H3M w 2 H2 1.04 0.42 0 asgn 303 w 2 H1M w 2 H1M 1476.08 590.43 6 ovlp 303 w 2 H2M w 2 H1M 1476.08 590.43 6 ovlp 303 w 2 H3M w 2 H1M 1476.08 590.43 6 ovlp 303 w 2 H1M w 2 H2M 1476.08 590.43 6 ovlp 303 w 2 H2M w 2 H2M 1476.08 590.43 6 ovlp 303 w 2 H3M w 2 H2M 1476.08 590.43 6 ovlp 303 w 2 H1M w 2 H3M 1476.08 590.43 6 ovlp 303 w 2 H2M w 2 H3M 1476.08 590.43 6 ovlp 303 w 2 H3M w 2 H3M 1476.08 590.43 6 asgn 73 w 2 H1M w′ 1 H3 0.57 0.23 0 ovlp 73 w 2 H2M w′ 1 H3 0.57 0.23 0 ovlp 73 w 2 H3M w′ 1 H3 0.57 0.23 0 asgn 74 w′ 1 H1 w′ 1 H1 311.90 124.76 0 asgn 75 w′ 1 H3 w′ 1 H1 8.22 3.29 0 asgn 76 w 2 H1M w′ 1 H1 1.09 0.44 0 ovlp 76 w 2 H2M w′ 1 H1 1.09 0.44 0 ovlp 76 w 2 H3M w′ 1 H1 1.09 0.44 0 asgn 77 w 2 H2 w′ 1 H1 0.91 0.37 0 asgn 78 w 2 H3 w′ 1 H1 25.86 10.34 0 ovlp 78 w′ 1 H5 w′ 1 H1 25.86 10.34 0 asgn 79 w′ 1 H1 w 2 H4 0.32 0.13 0 asgn 80 w 2 H1 f′ 3 H3 0.71 0.28 0 asgn 81 w′ 1 H2 w′ 1 H2 265.54 106.31 0 asgn 82 w′ 1 H5 w′ 1 H2 1.33 0.56 0 asgn 83 a′ 5 H3 g 4 H1 0.35 0.14 0 asgn 84 a 6 H1M a 6 H1 0.40 0.16 0 ovlp 84 a 6 H2M a 6 H1 0.40 0.16 0 ovlp 84 a 6 H3M a 6 H1 0.40 0.16 0 asgn 85 a 6 H1M a 6 H2 0.40 0.17 0 ovlp 85 a 6 H2M a 6 H2 0.40 0.17 0 ovlp 85 a 6 H3M a 6 H2 0.40 0.17 0 remark noNOEs asgn 101 a′ 5 H2 a 6 H1 0.00 0.14 0 asgn 102 a′ 5 H3 a 6 H1 0.00 0.03 0 asgn 103 a′ 5 H4 a 6 H1 0.00 0.23 0 asgn 104 a 6 H61 a 6 H1 0.00 0.35 0 asgn 105 a′ 5 H1 a 6 H1 0.00 0.05 0 asgn 106 a 6 H61 a 6 H2 0.00 0.12 0 asgn 107 a 6 H62 a 6 H2 0.00 0.11 0 asgn 108 a 6 H5 a 6 H2 0.00 0.38 0 asgn 109 a′ 5 H5 a 6 H2 0.00 0.08 0 asgn 110 a′ 5 H3 a 6 H2 0.00 0.14 0 asgn 111 a′ 5 H2 a 6 H2 0.00 0.06 0 asgn 112 a 6 H61 a 6 H2N 0.00 0.02 0 asgn 113 a 6 H62 a 6 H2N 0.00 0.02 0 asgn 114 a 6 H5 a 6 H2N 0.00 0.15 0 asgn 115 a′ 5 H4 a 6 H2N 0.00 0.02 0 asgn 116 g 4 H1M a′ 5 H1 0.00 0.12 0 ovlp 116 g 4 H2M a′ 5 H1 0.00 0.12 0 ovlp 116 g 4 H3M a′ 5 H1 0.00 0.12 0 asgn 117 a 6 H4 a′ 5 H1 0.00 0.14 0 asgn 118 a 6 H5 a′ 5 H1 0.00 0.23 0 asgn 119 a 6 H61 a′ 5 H1 0.00 0.09 0 asgn 120 a 6 H62 a′ 5 H1 0.00 0.09 0 asgn 121 g 4 H2N a′ 5 H1 0.00 0.04 0 asgn 122 g 4 H2 a′ 5 H1 0.00 0.14 0 asgn 123 g 4 H4 a′ 5 H1 0.00 0.14 0 asgn 124 g 4 H5 a′ 5 H1 0.00 0.13 0 asgn 125 g 4 H61 a′ 5 H1 0.00 0.30 0 asgn 126 g 4 H1M a′ 5 H2 0.00 0.10 0 ovlp 126 g 4 H2M a′ 5 H2 0.00 0.10 0 ovlp 126 g 4 H3M a′ 5 H2 0.00 0.10 0 asgn 127 a 6 H61 a′ 5 H2 0.00 0.29 0 asgn 128 a 6 H62 a′ 5 H2 0.00 0.22 0 asgn 129 g 4 H62 a′ 5 H2 0.00 0.22 0 asgn 130 a 6 H2 a′ 5 H2 0.00 0.12 0 asgn 131 a 6 H4 a′ 5 H2 0.00 0.20 0 asgn 132 a 6 H1M a′ 5 H2 0.00 0.10 0 ovlp 132 a 6 H2M a′ 5 H2 0.00 0.10 0 ovlp 132 a 6 H3M a′ 5 H2 0.00 0.10 0 asgn 133 w 2 H1M f′ 3 H1 0.00 0.91 0 ovlp 133 w 2 H2M f′ 3 H1 0.00 0.91 0 ovlp 133 w 2 H3M f′ 3 H1 0.00 0.91 0 asgn 134 g 4 H4 f′ 3 H1 0.00 0.27 0 asgn 135 g 4 H5 f′ 3 H1 0.00 1.17 0 asgn 136 g 4 H61 f′ 3 H1 0.00 0.16 0 asgn 137 g 4 H62 f′ 3 H1 0.00 0.27 0 asgn 138 w 2 H5 f′ 3 H1 0.00 1.17 0 asgn 139 w 2 H61 f′ 3 H1 0.00 0.16 0 asgn 140 w 2 H62 f′ 3 H1 0.00 0.27 0 asgn 141 w 2 H1M f′ 3 H1 0.00 0.91 0 ovlp 141 w 2 H2M f′ 3 H1 0.00 0.91 0 ovlp 141 w 2 H3M f′ 3 H1 0.00 0.91 0 asgn 142 g 4 H1M f′ 3 H2 0.00 0.06 0 ovlp 142 g 4 H2M f′ 3 H2 0.00 0.06 0 ovlp 142 g 4 H3M f′ 3 H2 0.00 0.06 0 asgn 143 w 2 H61 f′ 3 H2 0.00 0.09 0 asgn 144 w 2 H62 f′ 3 H2 0.00 0.04 0 asgn 145 g 4 H61 f′ 3 H2 0.00 0.09 0 asgn 146 g 4 H62 f′ 3 H2 0.00 0.04 0 asgn 147 g 4 H1 f′ 3 H2 0.00 0.26 0 asgn 148 g 4 H1M f′ 3 H4 0.00 0.09 0 ovlp 148 g 4 H2M f′ 3 H4 0.00 0.09 0 ovlp 148 g 4 H3M f′ 3 H4 0.00 0.09 0 asgn 149 w 2 H1M f′ 3 H4 0.00 0.11 0 ovlp 149 w 2 H2M f′ 3 H4 0.00 0.11 0 ovlp 149 w 2 H3M f′ 3 H4 0.00 0.11 0 asgn 150 g 4 H4 g 4 H1 0.00 0.43 0 asgn 151 g 4 H61 g 4 H1 0.00 0.26 0 asgn 152 f′ 3 H1 g 4 H1 0.00 0.53 0 asgn 153 f′ 3 H2 g 4 H1 0.00 0.31 0 asgn 154 f′ 3 H3 g 4 H1 0.00 0.13 0 asgn 155 f′ 3 H4 g 4 H1 0.00 3.40 0 asgn 156 g 4 H62 g 4 H1 0.00 0.17 0 asgn 157 g 4 H61 g 4 H2N 0.00 0.05 0 asgn 158 g 4 H62 g 4 H2N 0.00 0.04 0 asgn 159 a′ 5 H1 g 4 H2N 0.00 0.43 0 asgn 160 f′ 3 H4 g 4 H2N 0.00 0.20 0 asgn 161 a′ 5 H2 g 4 H2N 0.00 0.04 0 asgn 162 a′ 5 H3 g 4 H2N 0.00 0.17 0 asgn 163 g 4 H1M g 4 H4 0.00 0.03 0 ovlp 163 g 4 H2M g 4 H4 0.00 0.03 0 ovlp 163 g 4 H3H g 4 H4 0.00 0.03 0 asgn 164 g 4 H1M g 4 H5 0.00 0.06 0 ovlp 164 g 4 H2M g 4 H5 0.00 0.06 0 ovlp 164 g 4 H3M g 4 H5 0.00 0.06 0 asgn 165 g 4 H1M g 4 H61 0.00 0.02 0 ovlp 165 g 4 H2M g 4 H61 0.00 0.02 0 ovlp 165 g 4 H3M g 4 H61 0.00 0.02 0 asgn 166 g 4 H1M g 4 H62 0.00 0.04 0 ovlp 166 g 4 H2M g 4 H62 0.00 0.04 0 ovlp 166 g 4 H3M g 4 H62 0.00 0.04 0 asgn 167 w′ 1 H1 w 2 H1 0.00 0.54 0 asgn 168 w′ 1 H2 w 2 H1 0.00 0.06 0 asgn 169 w′ 1 H3 w 2 H1 0.00 7.41 0 asgn 170 w′ 1 H4 w 2 H1 0.00 7.41 0 asgn 171 w 2 H4 w 2 H1 0.00 0.37 0 asgn 172 w 2 H61 w 2 H1 0.00 0.31 0 asgn 173 w 2 H62 w 2 H1 0.00 0.16 0 asgn 174 f′ 3 H3 w 2 H1 0.00 0.16 0 asgn 175 w 2 H61 w 2 H2N 0.00 0.07 0 asgn 176 w 2 H62 w 2 H2N 0.00 0.04 0 asgn 177 f′ 3 H3 w 2 H2N 0.00 0.04 0 asgn 178 w′ 1 H4 w 2 H2N 0.00 0.10 0 asgn 179 f′ 3 H2 w 2 H2N 0.00 0.04 0 asgn 180 w 2 H1M w 2 H3 0.00 0.24 0 ovlp 180 w 2 H2M w 2 H3 0.00 0.24 0 ovlp 180 w 2 H3M w 2 H3 0.00 0.24 0 asgn 181 w 2 H1M w 2 H4 0.00 0.08 0 ovlp 181 w 2 H2M w 2 H4 0.00 0.08 0 ovlp 181 w 2 H3M w 2 H4 0.00 0.08 0 asgn 182 w 2 H1M w 2 H5 0.00 0.04 0 ovlp 182 w 2 H2M w 2 H5 0.00 0.04 0 ovlp 182 w 2 H3M w 2 H5 0.00 0.04 0 asgn 183 w 2 H1M w 2 H61 0.00 0.02 0 ovlp 183 w 2 H2M w 2 H61 0.00 0.02 0 ovlp 183 w 2 H3M w 2 H61 0.00 0.02 0 asgn 184 w 2 H1M w 2 H62 0.00 0.04 0 ovlp 184 w 2 H2M w 2 H62 0.00 0.04 0 ovlp 184 w 2 H3M w 2 H62 0.00 0.04 0 asgn 185 w′ 1 H4 w′ 1 H1 0.00 2.83 0 asgn 186 w 2 H4 w′ 1 H1 0.00 0.31 0 asgn 187 w 2 H5 w′ 1 H1 0.00 0.69 0 asgn 188 w 2 H61 w′ 1 H1 0.00 0.10 0 asgn 189 w 2 H62 w′ 1 H1 0.00 0.07 0 asgn 190 w 2 H1M w′ 1 H2 0.00 0.64 0 ovlp 190 w 2 H2M w′ 1 H2 0.00 0.64 0 ovlp 190 w 2 H3M w′ 1 H2 0.00 0.64 0 asgn 191 w 2 H62 w′ 1 H2 0.00 0.05 0 asgn 192 w 2 H4 w′ 1 H2 0.00 0.34 0 asgn 193 w 2 H1 w′ 1 H2 0.00 0.04 0 asgn 194 w 2 H1M w′ 1 H2 0.00 0.08 0 ovlp 194 w 2 H2M w′ 1 H2 0.00 0.08 0 ovlp 194 w 2 H3M w′ 1 H2 0.00 0.08 0 endsection

[¹H-¹⁵N]-NOESY-HSQC Dataset for a Hyaluronan Hexasaccharide

remark 15N-NOESY-HSQC data for alpha-HA6 configuration: field 750 solvent h2o ident 15N-NOESY-HSQC temp 298 visc 0.88 mix_time 400 ms endsection data: asgn 1 a 6 H1M a 6 H2N 48.8 19.6 0 ovlp 1 a 6 H2M a 6 H2N 48.8 19.6 0 ovlp 1 a 6 H3M a 6 H2N 48.8 19.6 0 asgn 2 a 6 H3 a 6 H2N 34.2 13.7 0 asgn 3 a 6 H2 a 6 H2N 12.6 5.1 0 asgn 4 a′ 5 H1 a 6 H2N 58.7 23.5 0 asgn 5 a 6 H1 a 6 H2N 22.4 9.0 0 asgn 6 a 6 H2N a 6 H2N 1918.9 767.6 0 asgn 7 a′ 5 H5 a 6 H2N 7.9 3.3 0 asgn 8 w 2 H1M w 2 H2N 93.9 37.6 0 ovlp 8 w 2 H2M w 2 H2N 93.9 37.6 0 ovlp 8 w 2 H3M w 2 H2N 93.9 37.6 0 asgn 9 w 2 H3 w 2 H2N 126.8 50.7 0 ovlp 9 w′ 1 H5 w 2 H2N 126.8 50.7 0 ovlp 9 f′ 3 H5 w 2 H2N 126.8 50.7 0 asgn 10 w 2 H2 w 2 H2N 30.2 12.1 0 asgn 11 w′ 1 H1 w 2 H2N 109.6 43.8 0 asgn 12 w 2 H1 w 2 H2N 74.8 29.9 0 asgn 13 w 2 H2N w 2 H2N 3575.4 1430.2 0 asgn 14 g 4 H1M g 4 H2N 120.9 48.4 0 ovlp 14 g 4 H2M g 4 H2N 120.9 48.4 0 ovlp 14 g 4 H3M g 4 H2N 120.9 48.4 0 asgn 15 g 4 H3 g 4 H2N 118.5 47.4 0 ovlp 15 a′ 5 H5 g 4 H2N 118.5 47.4 0 ovlp 15 f′ 3 H5 g 4 H2N 118.5 47.4 0 asgn 16 g 4 H2 g 4 H2N 35.4 14.2 0 asgn 17 f′ 3 H1 g 4 H2N 105.0 42.0 0 asgn 18 g 4 H1 g 4 H2N 89.6 35.9 0 asgn 19 g 4 H2N g 4 H2N 2955.4 1182.3 0 endsection

[¹H-¹H]-T-ROESY Dataset for a Hyaluronan Hexasaccharide

remark 2D-T-ROESY data for alpha-HA6 configuration: field 600 solvent d2o ident 2D-TROESY temp 298 visc 1.08 mix_time 400 ms endsection data: asgn 1 a 6 H1 a 6 H1 2404.98 1202.49 0 asgn 2 a 6 H1 a 6 H2 −87.92 44.04 0 asgn 3 a 6 H1 a 6 H3 −10.51 5.38 0 asgn 4 a 6 H1 a 6 H4 −2.06 1.12 0 asgn 5 a 6 H1 a 6 H5 −4.60 2.31 0 asgn 6 a 6 H2 a 6 H1 −91.54 46.02 0 asgn 7 a 6 H2 a 6 H2 1994.95 1001.93 0 asgn 8 a 6 H2 a 6 H4 −37.45 19.18 0 asgn 9 a 6 H2 a′ 5 H1 −12.85 6.45 0 asgn 10 a 6 H3 a′ 5 H1 −36.87 18.44 0 asgn 11 a 6 H4 a 6 H2 −35.65 17.84 0 asgn 12 a 6 H1M a 6 H1 −1.78 0.91 0 ovlp 12 a 6 H2M a 6 H1 −1.78 0.91 0 ovlp 12 a 6 H3M a 6 H1 −1.78 0.91 0 asgn 13 a 6 H1M a 6 H2 −4.89 2.48 0 ovlp 13 a 6 H2M a 6 H2 −4.89 2.48 0 ovlp 13 a 6 H3M a 6 H2 −4.89 2.48 0 asgn 14 a 6 H1M a 6 H3 −2.53 1.32 0 ovlp 14 a 6 H2M a 6 H3 −2.53 1.32 0 ovlp 14 a 6 H3M a 6 H3 −2.53 1.32 0 asgn 15 a 6 H1M a′ 5 H1 −3.88 1.95 0 ovlp 15 a 6 H2M a′ 5 H1 −3.88 1.95 0 ovlp 15 a 6 H3M a′ 5 H1 −3.88 1.95 0 asgn 16 a′ 5 H1 a 6 H2 −5.55 2.79 0 asgn 17 a′ 5 H1 a 6 H3 −56.88 28.48 0 asgn 18 a′ 5 H1 a 6 H4 −6.00 3.03 0 asgn 19 a′ 5 H1 a′ 5 H1 573.02 286.71 0 asgn 20 a′ 5 H1 a′ 5 H3 −34.08 17.04 0 asgn 21 a′ 5 H1 a′ 5 H4 −18.12 9.88 0 asgn 22 a′ 5 H1 a′ 5 H5 −24.25 12.97 0 asgn 23 a′ 5 H2 a 6 H3 −5.63 2.84 0 asgn 24 a′ 5 H2 a′ 5 H2 642.51 326.60 0 asgn 25 a′ 5 H3 a′ 5 H1 −19.80 9.90 0 asgn 26 a′ 5 H4 a′ 5 H1 −17.16 8.59 0 asgn 27 a′ 5 H4 a′ 5 H2 −27.04 13.53 0 asgn 28 a′ 5 H5 a′ 5 H1 −43.88 21.95 0 asgn 29 f′ 3 H1 f′ 3 H1 624.53 312.27 0 asgn 30 f′ 3 H2 f′ 3 H2 516.19 269.50 0 asgn 31 f′ 3 H3 f′ 3 H1 −21.99 11.00 0 asgn 32 f′ 3 H4 f′ 3 H2 −24.69 13.33 0 asgn 33 g 4 H1M f′ 3 H3 −7.80 3.92 0 ovlp 33 g 4 H2M f′ 3 H3 −7.80 3.92 0 ovlp 33 g 4 H3M f′ 3 H3 −7.80 3.92 0 asgn 34 w 2 H4 w′ 1 H1 −3.07 1.54 0 asgn 35 w 2 H1M w′ 1 H2 −4.04 2.04 0 ovlp 35 w 2 H2M w′ 1 H2 −4.04 2.04 0 ovlp 35 w 2 H3M w′ 1 H2 −4.04 2.04 0 asgn 36 w 2 H1M w′ 1 H3 −3.75 1.89 0 ovlp 36 w 2 H2M w′ 1 H3 −3.75 1.89 0 ovlp 36 w 2 H3M w′ 1 H3 −3.75 1.89 0 asgn 37 w′ 1 H1 w 2 H4 −4.45 2.23 0 asgn 38 w′ 1 H1 w′ 1 H1 624.53 312.27 0 asgn 39 w′ 1 H1 w′ 1 H3 −31.07 15.54 0 asgn 40 w′ 1 H2 w′ 1 H2 666.60 333.91 0 asgn 41 w′ 1 H3 w′ 1 H1 −28.71 14.36 0 asgn 42 g 4 H1 g 4 H1 1507.50 754.78 0 ovlp 42 w 2 H1 w 2 H1 1507.50 754.78 0 asgn 43 g 4 H1 g 4 H5 −84.68 42.69 0 ovlp 43 w 2 H1 w 2 H5 −84.68 42.69 0 asgn 44 g 4 H5 g 4 H1 −73.73 37.22 0 ovlp 44 w 2 H5 w 2 H1 −73.73 37.22 0 asgn 45 g 4 H2 f′ 3 H1 −10.58 5.29 0 ovlp 45 w 2 H2 w′ 1 H1 −10.58 5.29 0 asgn 46 f′ 3 H1 g 4 H2 −9.46 4.73 0 ovlp 46 w′ 1 H1 w 2 H2 −9.46 4.73 0 asgn 47 f′ 3 H3 w 2 H1 −4.07 2.26 0 asgn 48 a′ 5 H3 g 4 H1 −6.92 3.85 0 asgn 49 g 4 H1 a′ 5 H3 −2.86 1.58 0 asgn 50 f′ 3 H1 f′ 3 H3 −38.94 19.48 0 asgn 51 f′ 3 H4 w 2 H1 −46.75 23.38 0 asgn 52 a′ 5 H4 g 4 H1 −79.48 39.74 0 asgn 53 w 2 H1 f′ 3 H4 −26.68 13.53 0 asgn 54 g 4 H1 a′ 5 H4 −26.68 13.53 0 asgn 55 g 4 H1 g 4 H3 −14.33 8.23 0 ovlp 55 g 4 H1 f′ 3 H3 −14.33 8.23 0 ovlp 55 g 4 H1 a′ 5 H5 −14.33 8.23 0 asgn 56 w 2 H1 w 2 H3 −14.33 8.23 0 ovlp 56 w 2 H1 w′ 1 H3 −14.33 8.23 0 ovlp 56 w 2 H1 f′ 3 H5 −14.33 8.23 0 asgn 57 g 4 H1M f′ 3 H1 −4.72 2.36 0 ovlp 57 g 4 H2M f′ 3 H1 −4.72 2.36 0 ovlp 57 g 4 H3M f′ 3 H1 −4.72 2.36 0 asgn 58 w 2 H1M w′ 1 H1 −4.72 2.36 0 ovlp 58 w 2 H2M w′ 1 H1 −4.72 2.36 0 ovlp 58 w 2 H3M w′ 1 H1 −4.72 2.36 0 asgn 59 g 4 H1M g 4 H1 −1.29 0.65 0 ovlp 59 g 4 H2M g 4 H1 −1.29 0.65 0 ovlp 59 g 4 H3M g 4 H1 −1.29 0.65 0 asgn 60 w 2 H1M w 2 H1 −1.29 0.65 0 ovlp 60 w 2 H2M w 2 H1 −1.29 0.65 0 ovlp 60 w 2 H3M w 2 H1 −1.29 0.65 0 asgn 61 g 4 H1M g 4 H2 −4.24 2.13 0 ovlp 61 g 4 H2M g 4 H2 −4.24 2.13 0 ovlp 61 g 4 H3M g 4 H2 −4.24 2.13 0 asgn 62 w 2 H1M w 2 H2 −4.24 2.13 0 ovlp 62 w 2 H2M w 2 H2 −4.24 2.13 0 ovlp 62 w 2 H3M w 2 H2 −4.24 2.13 0 remark noROES asgn 101 g 4 H1M a 6 H1 0.00 0.59 0 ovlp 101 g 4 H2M a 6 H1 0.00 0.59 0 ovlp 101 g 4 H3M a 6 H1 0.00 0.59 0 asgn 102 a′ 5 H2 a 6 H1 0.00 0.57 0 asgn 103 a′ 5 H3 a 6 H1 0.00 0.74 0 asgn 104 a′ 5 H4 a 6 H1 0.00 1.10 0 asgn 105 a 6 H61 a 6 H1 0.00 0.92 0 asgn 106 a′ 5 H1 a 6 H1 0.00 0.80 0 asgn 107 a 6 H61 a 6 H2 0.00 2.46 0 asgn 108 a 6 H62 a 6 H2 0.00 1.83 0 asgn 109 a 6 H5 a 6 H2 0.00 6.56 0 asgn 110 a′ 5 H5 a 6 H2 0.00 3.79 0 asgn 111 a′ 5 H3 a 6 H2 0.00 4.19 0 asgn 112 a′ 5 H2 a 6 H2 0.00 1.01 0 asgn 113 g 4 H1M a′ 5 H1 0.00 2.05 0 ovlp 113 g 4 H2M a′ 5 H1 0.00 2.05 0 ovlp 113 g 4 H3M a′ 5 H1 0.00 2.05 0 asgn 114 a 6 H4 a′ 5 H1 0.00 0.55 0 asgn 115 a 6 H5 a′ 5 H1 0.00 1.67 0 asgn 116 a 6 H61 a′ 5 H1 0.00 1.52 0 asgn 117 a 6 H62 a′ 5 H1 0.00 1.67 0 asgn 118 g 4 H2 a′ 5 H1 0.00 1.67 0 asgn 119 g 4 H3 a′ 5 H1 0.00 7.90 0 asgn 120 g 4 H4 a′ 5 H1 0.00 0.79 0 asgn 121 g 4 H5 a′ 5 H1 0.00 0.68 0 asgn 122 g 4 H61 a′ 5 H1 0.00 1.89 0 asgn 123 w 2 H1M a′ 5 H1 0.00 2.05 0 ovlp 123 w 2 H2M a′ 5 H1 0.00 2.05 0 ovlp 123 w 2 H3M a′ 5 H1 0.00 2.05 0 asgn 124 a 6 H61 a′ 5 H2 0.00 1.19 0 asgn 125 a 6 H62 a′ 5 H2 0.00 1.69 0 asgn 126 g 4 H62 a′ 5 H2 0.00 0.54 0 asgn 127 a 6 H1 a′ 5 H2 0.00 0.32 0 asgn 128 a 6 H2 a′ 5 H2 0.00 1.31 0 asgn 129 a 6 H4 a′ 5 H2 0.00 3.91 0 asgn 130 a 6 H1M a′ 5 H2 0.00 3.55 0 ovlp 130 a 6 H2M a′ 5 H2 0.00 3.55 0 ovlp 130 a 6 H3M a′ 5 H2 0.00 3.55 0 asgn 131 w 2 H1M f′ 3 H1 0.00 4.08 0 ovlp 131 w 2 H2M f′ 3 H1 0.00 4.08 0 ovlp 131 w 2 H3M f′ 3 H1 0.00 4.08 0 asgn 132 g 4 H4 f′ 3 H1 0.00 3.40 0 asgn 133 g 4 H5 f′ 3 H1 0.00 0.95 0 asgn 134 g 4 H61 f′ 3 H1 0.00 2.72 0 asgn 135 g 4 H62 f′ 3 H1 0.00 1.72 0 asgn 136 w 2 H4 f′ 3 H1 0.00 0.96 0 asgn 137 w 2 H5 f′ 3 H1 0.00 0.95 0 asgn 138 w 2 H61 f′ 3 H1 0.00 2.72 0 asgn 139 w 2 H62 f′ 3 H1 0.00 1.72 0 asgn 140 w 2 H1M f′ 3 H2 0.00 2.19 0 ovlp 140 w 2 H2M f′ 3 H2 0.00 2.19 0 ovlp 140 w 2 H3M f′ 3 H2 0.00 2.19 0 asgn 141 w 2 H62 f′ 3 H2 0.00 0.88 0 asgn 142 g 4 H62 f′ 3 H2 0.00 0.88 0 asgn 143 g 4 H1 f′ 3 H2 0.00 1.05 0 asgn 144 g 4 H1M f′ 3 H4 0.00 1.92 0 ovlp 144 g 4 H2M f′ 3 H4 0.00 1.92 0 ovlp 144 g 4 H3M f′ 3 H4 0.00 1.92 0 asgn 145 g 4 H62 g 4 H1 0.00 1.21 0 asgn 146 f′ 3 H1 g 4 H1 0.00 5.64 0 asgn 147 f′ 3 H2 g 4 H1 0.00 0.18 0 asgn 148 a′ 5 H3 g 4 H1 0.00 0.83 0 asgn 149 g 4 H1M g 4 H4 0.00 1.39 0 ovlp 149 g 4 H2M g 4 H4 0.00 1.39 0 ovlp 149 g 4 H3M g 4 H4 0.00 1.39 0 asgn 150 g 4 H1M g 4 H61 0.00 1.28 0 ovlp 150 g 4 H2M g 4 H61 0.00 1.28 0 ovlp 150 g 4 H3M g 4 H61 0.00 1.28 0 asgn 151 g 4 H1M g 4 H62 0.00 1.47 0 ovlp 151 g 4 H2M g 4 H62 0.00 1.47 0 ovlp 151 g 4 H3M g 4 H62 0.00 1.47 0 asgn 152 w′ 1 H1 w 2 H1 0.00 5.64 0 asgn 153 w′ 1 H2 w 2 H1 0.00 0.18 0 asgn 154 w 2 H62 w 2 H1 0.00 0.83 0 asgn 155 w 2 H1M w 2 H4 0.00 1.44 0 ovlp 155 w 2 H2M w 2 H4 0.00 1.44 0 ovlp 155 w 2 H3M w 2 H4 0.00 1.44 0 asgn 156 w 2 H1M w 2 H5 0.00 1.60 0 ovlp 156 w 2 H2M w 2 H5 0.00 1.60 0 ovlp 156 w 2 H3M w 2 H5 0.00 1.60 0 asgn 157 w 2 H1M w 2 H61 0.00 1.28 0 ovlp 157 w 2 H2M w 2 H61 0.00 1.28 0 ovlp 157 w 2 H3M w 2 H61 0.00 1.28 0 asgn 158 w 2 H1M w 2 H62 0.00 1.47 0 ovlp 158 w 2 H2M w 2 H62 0.00 1.47 0 ovlp 158 w 2 H3M w 2 H62 0.00 1.47 0 asgn 159 w 2 H61 w′ 1 H1 0.00 2.72 0 asgn 160 w 2 H62 w′ 1 H1 0.00 1.72 0 asgn 161 w 2 H62 w′ 1 H2 0.00 0.59 0 asgn 162 w 2 H4 w′ 1 H2 0.00 1.97 0 asgn 163 w 2 H1 w′ 1 H2 0.00 0.63 0 endsection

[¹H-¹⁵N]-T-ROESY-HSQC Dataset for a Hyaluronan Hexasaccharide

remark 15N-T-ROESY-HSQC data for alpha-HA6 configuration: field 600 solvent h2o temp 298 visc 0.88 ident 15N-TROESY-HSQC mix_time 400 ms endsection data: asgn 1 a 6 H1M a 6 H2N −17.0 3.4 0 ovlp 1 a 6 H2M a 6 H2N −17.0 3.4 0 ovlp 1 a 6 H3M a 6 H2N −17.0 3.4 0 asgn 2 a 6 H3 a 6 H2N −13.1 2.6 0 asgn 3 a 6 H2 a 6 H2N −8.9 1.8 0 asgn 4 a′ 5 H1 a 6 H2N −9.5 1.9 0 asgn 5 a 6 H1 a 6 H2N −5.1 1.0 0 asgn 6 a 6 H2N a 6 H2N 332.3 66.5 0 asgn 7 w 2 H1M w 2 H2N −22.9 4.6 0 ovlp 7 w 2 H2M w 2 H2N −22.9 4.6 0 ovlp 7 w 2 H3M w 2 H2N −22.9 4.6 0 asgn 8 w 2 H3 w 2 H2N −16.3 3.3 0 ovlp 8 w′ 1 H5 w 2 H2N −16.3 3.3 0 ovlp 8 f′ 3 H5 w 2 H2N −16.3 3.3 0 asgn 9 w 2 H2 w 2 H2N −12.5 2.5 0 asgn 10 w′ 1 H1 w 2 H2N −13.1 2.6 0 asgn 11 w 2 H1 w 2 H2N −18.7 3.7 0 asgn 12 w 2 H2N w 2 H2N 437.9 87.6 0 asgn 13 g 4 H1M g 4 H2N −18.2 3.6 0 ovlp 13 g 4 H2M g 4 H2N −18.2 3.6 0 ovlp 13 g 4 H3M g 4 H2N −18.2 3.6 0 asgn 14 g 4 H3 g 4 H2N −13.8 2.8 0 ovlp 14 f′ 3 H5 g 4 H2N −13.8 2.8 0 ovlp 14 a′ 5 H5 g 4 H2N −13.8 2.8 0 asgn 15 g 4 H2 g 4 H2N −10.7 2.1 0 asgn 16 f′ 3 H1 g 4 H2N −12.3 2.5 0 asgn 17 g 4 H1 g 4 H2N −15.3 3.1 0 asgn 18 g 4 H2N g 4 H2N 348.4 69.7 0 endsection

Scalar-Coupling Dataset for a Hyaluronan Hexasaccharide

remark Conformation-dependent scalar couplings configuration: field 900 solvent h2o ident JCOUP endsection data: remark atoms karplus c1 c2 c3 phase experimental error coup 1 2 H2 2 C2 2 N2 2 H2N 9.45 −2.08 0.63 0 9.67 0.5 0 coup 2 4 H2 4 C2 4 N2 4 H2N 9.45 −2.08 0.63 0 9.75 0.5 0 coup 3 6 H2 6 C2 6 N2 6 H2N 9.81 −1.51 0.62 0 9.38 0.5 0 endsection

Residual Dipolar Coupling Dataset for a Hyaluronan Hexasaccharide

remark Residual dipolar couplings for alpha-HA6 configuration: field 900 solvent h2o ident RDC endsection data: asgn 1 a 6 C1 a 6 H1 −5.85 0.35 0 asgn 2 a 6 C2 a 6 H2 0.69 0.35 0 asgn 3 a 6 C3 a 6 H3 −1.06 0.35 0 asgn 4 a 6 C5 a 6 H5 −1.23 0.35 0 asgn 5 a 6 C6 a 6 H61 −1.32 0.35 0 asgn 6 a 6 C6 a 6 H62 −0.83 0.35 0 asgn 7 a 6 CME a 6 H1M −1.11 0.35 0 ovlp 7 a 6 CME a 6 H2M −1.11 0.35 0 ovlp 7 a 6 CME a 6 H3M −1.11 0.35 0 asgn 8 a′ 5 C1 a′ 5 H1 4.37 0.35 0 asgn 9 a′ 5 C2 a′ 5 H2 5.33 0.35 0 asgn 10 a′ 5 C3 a′ 5 H3 5.20 0.35 0 asgn 11 a′ 5 C4 a′ 5 H4 3.96 0.35 0 asgn 12 g 4 C1 g 4 H1 4.12 0.35 0 asgn 13 g 4 C2 g 4 H2 5.40 0.35 0 asgn 14 g 4 C3 g 4 H3 4.38 0.35 0 asgn 15 g 4 C4 g 4 H4 5.38 0.35 0 asgn 16 g 4 CME g 4 H1M −1.61 0.35 0 ovlp 16 g 4 CME g 4 H2M −1.61 0.35 0 ovlp 16 g 4 CME g 4 H3M −1.61 0.35 0 asgn 17 f′ 3 C1 f′ 3 H1 3.14 0.35 0 asgn 18 f′ 3 C2 f′ 3 H2 4.61 0.35 0 asgn 19 f′ 3 C3 f′ 3 H3 4.61 0.35 0 asgn 20 f′ 3 C4 f′ 3 H4 2.58 0.35 0 asgn 21 f′ 3 C5 f′ 3 H5 3.63 0.35 0 asgn 22 w 2 C1 w 2 H1 4.63 0.35 0 asgn 23 w 2 C2 w 2 H2 5.18 0.35 0 asgn 24 w 2 C3 w 2 H3 4.95 0.35 0 asgn 25 w 2 C4 w 2 H4 5.34 0.35 0 asgn 26 w 2 CME w 2 H1M −1.83 0.35 0 ovlp 26 w 2 CME w 2 H2M −1.83 0.35 0 ovlp 26 w 2 CME w 2 H3M −1.83 0.35 0 asgn 27 w′ 1 C1 w′ 1 H1 1.42 0.35 0 asgn 28 w′ 1 C2 w′ 1 H2 2.60 0.35 0 asgn 29 w′ 1 C3 w′ 1 H3 2.43 0.35 0 asgn 30 w′ 1 C4 w′ 1 H4 1.13 0.35 0 asgn 31 w′ 1 C5 w′ 1 H5 2.10 0.35 0 asgn 101 a 6 H2 a 6 H1 0.10 0.35 0 ovlp 101 a 6 H2 a 6 H3 0.10 0.35 0 asgn 102 a 6 H3 a 6 H2 −1.01 0.35 0 ovlp 102 a 6 H3 a 6 H4 −1.01 0.35 0 asgn 103 a 6 H4 a 6 H3 3.12 0.35 0 ovlp 103 a 6 H4 a 6 H5 3.12 0.35 0 asgn 104 a 6 H5 a 6 H4 6.45 0.35 0 ovlp 104 a 6 H5 a 6 H61 6.45 0.35 0 ovlp 104 a 6 H5 a 6 H62 6.45 0.35 0 asgn 105 a 6 H62 a 6 H61 −3.23 0.35 0 ovlp 105 a 6 H62 a 6 H5 −3.23 0.35 0 asgn 106 a′ 5 H1 a′ 5 H2 0.78 0.35 0 asgn 107 a′ 5 H2 a′ 5 H1 1.09 0.35 0 ovlp 107 a′ 5 H2 a′ 5 H3 1.09 0.35 0 asgn 108 a′ 5 H3 a′ 5 H2 1.27 0.35 0 ovlp 108 a′ 5 H3 a′ 5 H4 1.27 0.35 0 asgn 109 a′ 5 H4 a′ 5 H3 1.40 0.35 0 ovlp 109 a′ 5 H4 a′ 5 H5 1.40 0.35 0 asgn 110 g 4 H1 g 4 H2 −0.36 0.35 0 asgn 111 g 4 H2 g 4 H1 2.28 0.35 0 ovlp 111 g 4 H2 g 4 H3 2.28 0.35 0 asgn 112 g 4 H3 g 4 H2 1.37 0.35 0 ovlp 112 g 4 H3 g 4 H4 1.37 0.35 0 asgn 113 g 4 H4 g 4 H3 1.61 0.35 0 ovlp 113 g 4 H4 g 4 H5 1.61 0.35 0 asgn 114 g 4 H62 g 4 H5 −3.35 0.35 0 ovlp 114 g 4 H62 g 4 H61 −3.35 0.35 0 asgn 115 f′ 3 H1 f′ 3 H2 −0.19 0.35 0 asgn 116 f′ 3 H2 f′ 3 H1 1.01 0.35 0 ovlp 116 f′ 3 H2 f′ 3 H3 1.01 0.35 0 asgn 117 f′ 3 H3 f′ 3 H2 1.33 0.35 0 ovlp 117 f′ 3 H3 f′ 3 H4 1.33 0.35 0 asgn 118 f′ 3 H4 f′ 3 H3 0.35 0.35 0 ovlp 118 f′ 3 H4 f′ 3 H5 0.35 0.35 0 asgn 119 f′ 3 H5 f′ 3 H4 −0.02 0.35 0 asgn 120 w 2 H1 w 2 H2 0.55 0.35 0 asgn 121 w 2 H2 w 2 H1 2.52 0.35 0 ovlp 121 w 2 H2 w 2 H3 2.52 0.35 0 asgn 122 w 2 H3 w 2 H2 1.19 0.35 0 ovlp 122 w 2 H3 w 2 H4 1.19 0.35 0 asgn 123 w′ 1 H1 w′ 1 H2 0.17 0.35 0 asgn 124 w′ 1 H2 w′ 1 H1 −0.37 0.35 0 ovlp 124 w′ 1 H2 w′ 1 H3 −0.37 0.35 0 asgn 125 w′ 1 H3 w′ 1 H2 0.59 0.35 0 ovlp 125 w′ 1 H3 w′ 1 H4 0.59 0.35 0 asgn 126 w′ 1 H4 w′ 1 H3 −0.37 0.35 0 ovlp 126 w′ 1 H4 w′ 1 H5 −0.37 0.35 0 asgn 127 w′ 1 H5 w′ 1 H4 −0.15 0.35 0 asgn 128 a 6 H2N a 6 H2 0.10 0.35 0 asgn 129 a 6 H1 a 6 H2 0.90 0.35 0 asgn 130 a′ 5 H1 a′ 5 H2 1.06 0.35 0 asgn 131 a 6 H2N a 6 N2 0.82 0.35 0 asgn 132 w 2 H2N w 2 N2 −1.30 0.35 0 asgn 133 g 4 H2N g 4 N2 −1.83 0.35 0 endsection

Order Parameter Dataset for a Hyaluronan Hexasaccharide

remark Order parameters for amide groups configuration: solvent  h2o ident  ORDER endsection data: hnoe 1 w 2 H2N w 2 N2 0.44 0.01 0 hnoe 2 g 4 H2N g 4 N2 0.57 0.01 0 hnoe 3 a 6 H2N a 6 N2 0.51 0.02 0 endsection

Final χ² _(restraint) Values for Each Structural Restraint after Structure Refinement

In this file the fields for each line are as follows: the first number is the structural restraint number (e.g., 123), this is followed by six letters or numbers defining the atoms involved in the structural restraint (e.g. w 2 H1M a′ 5 H1), the next two values define the structural restraint measurement and its error (e.g. 0.00 2.00), the next two three values gives the predicted value of this structural restraint from the dynamic ensemble(e.g. −0.00), the χ² _(restraint) value for this structural restraint (e.g. 0.00) and the standard deviation for the χ² _(restraint) value (e.g. 0.00). The next value is the flag value (e.g. 0), while the next value gives the number of overlaps the restraint had (e.g. +2). The final field gives the name of the dataset file the structural restraint is found in (e.g. 2D-ROESY). The structural restraints are sorted from lowest to highest χ² _(restraint) value in this file (i.e., restraint 123 in the 2D-T-ROESY dataset to restraint 104 in the RDC dataset).

123 w 2 H1M a′ 5 H1 0.00 2.00 −0.00 0.00 0.00 0 +2 2D-ROESY 170 w′ 1 H4 w 2 H1 0.00 7.40 0.01 0.00 0.00 0 +0 2D-NOESY 119 g 4 H3 a′ 5 H1 0.00 7.90 −0.01 0.00 0.00 0 +0 2D-ROESY 155 f′ 3 H4 g 4 H1 0.00 3.40 0.01 0.00 0.00 0 +0 2D-NOESY 169 w′ 1 H3 w 2 H1 0.00 7.40 0.02 0.00 0.00 0 +0 2D-NOESY 150 g 4 H1M g 4 H61 0.00 1.30 −0.00 0.00 0.00 0 +2 2D-ROESY 157 w 2 H1M w 2 H61 0.00 1.30 −0.00 0.00 0.00 0 +2 2D-ROESY 151 g 4 H1M g 4 H62 0.00 1.50 −0.01 0.00 0.00 0 +2 2D-ROESY 158 w 2 H1M w 2 H62 0.00 1.50 −0.01 0.00 0.00 0 +2 2D-ROESY 131 w 2 H1M f′ 3 H1 0.00 4.10 −0.02 0.00 0.00 0 +2 2D-ROESY 138 w 2 H61 f′ 3 H1 0.00 2.70 −0.02 0.00 0.00 0 +0 2D-ROESY 101 g 4 H1M a 6 H1 0.00 0.59 −0.00 0.00 0.00 0 +2 2D-ROESY 139 w 2 H62 f′ 3 H1 0.00 1.70 −0.01 0.00 0.00 0 +0 2D-ROESY 140 w 2 H1M f′ 3 H2 0.00 2.20 −0.02 0.00 0.00 0 +2 2D-ROESY 122 g 4 H61 a′ 5 H1 0.00 1.90 −0.02 0.00 0.00 0 +0 2D-ROESY 138 w 2 H5 f′ 3 H1 0.00 1.20 0.01 0.00 0.00 0 +0 2D-NOESY 113 g 4 H1M a′ 5 H1 0.00 2.00 −0.02 0.00 0.00 0 +2 2D-ROESY 146 f′ 3 H1 g 4 H1 0.00 5.60 0.03 0.00 0.00 0 +0 2D-ROESY 134 g 4 H61 f′ 3 H1 0.00 2.70 −0.03 0.00 0.00 0 +0 2D-ROESY 145 g 4 H62 g 4 H1 0.00 1.20 −0.01 0.00 0.00 0 +0 2D-ROESY 115 a 6 H5 a′ 5 H1 0.00 1.70 −0.02 0.00 0.00 0 +0 2D-ROESY 144 g 4 H1M f′ 3 H4 0.00 1.90 −0.01 0.00 0.00 0 +2 2D-ROESY 111 a′ 5 H3 a 6 H2 0.00 4.20 −0.06 0.00 0.00 0 +0 2D-ROESY 116 a 6 H61 a′ 5 H1 0.00 1.50 −0.02 0.00 0.00 0 +0 2D-ROESY 133 w 2 H1M f′ 3 H1 0.00 0.91 0.01 0.00 0.00 0 +2 2D-NOESY 141 w 2 H1M f′ 3 H1 0.00 0.91 0.01 0.00 0.00 0 +2 2D-NOESY 117 a 6 H62 a′ 5 H1 0.00 1.70 −0.03 0.00 0.00 0 +0 2D-ROESY 39 w′ 1 H1 w′ 1 H3 −31.00 16.00 −31.00 0.00 0.00 0 +0 2D-ROESY 152 w′ 1 H1 w 2 H1 0.00 5.60 0.06 0.00 0.00 0 +0 2D-ROESY 159 w 2 H61 w′ 1 H1 0.00 2.70 −0.05 0.00 0.00 0 +0 2D-ROESY 156 w 2 H1M w 2 H5 0.00 1.60 −0.03 0.00 0.00 0 +2 2D-ROESY 136 w 2 H4 f′ 3 H1 0.00 0.96 −0.02 0.00 0.00 0 +0 2D-ROESY 154 w 2 H62 w 2 H1 0.00 0.83 −0.01 0.00 0.00 0 +0 2D-ROESY 135 g 4 H62 f′ 3 H1 0.00 1.70 −0.03 0.00 0.00 0 +0 2D-ROESY 130 a 6 H1M a′ 5 H2 0.00 3.50 −0.07 0.00 0.00 0 +2 2D-ROESY 104 a′ 5 H4 a 6 H1 0.00 1.10 −0.02 0.00 0.00 0 +0 2D-ROESY 120 g 4 H4 a′ 5 H1 0.00 0.79 −0.02 0.00 0.00 0 +0 2D-ROESY 110 a′ 5 H5 a 6 H2 0.00 3.80 −0.09 0.00 0.00 0 +0 2D-ROESY 140 w 2 H62 f′ 3 H1 0.00 0.27 0.01 0.00 0.00 0 +0 2D-NOESY 103 a′ 5 H3 a 6 H1 0.00 0.74 −0.02 0.00 0.00 0 +0 2D-ROESY 103 a′ 5 H4 a 6 H1 0.00 0.23 0.01 0.00 0.00 0 +0 2D-NOESY 125 g 4 H61 a′ 5 H1 0.00 0.30 0.01 0.00 0.00 0 +0 2D-NOESY 137 w 2 H5 f′ 3 H1 0.00 0.95 −0.03 0.00 0.00 0 +0 2D-ROESY 118 g 4 H2 a′ 5 H1 0.00 1.70 −0.05 0.00 0.00 0 +0 2D-ROESY 159 a′ 5 H1 g 4 H2N 0.00 0.43 0.01 0.00 0.00 0 +0 2D-NOESY 160 w 2 H62 w′ 1 H1 0.00 1.70 −0.05 0.00 0.00 0 +0 2D-ROESY 117 f′ 3 H3 f′ 3 H2 1.30 0.35 1.30 0.00 0.00 0 +1 RDC 107 a 6 H61 a 6 H2 0.00 2.50 −0.09 0.00 0.00 0 +0 2D-ROESY 11 a 6 H4 a 6 H2 −36.00 18.00 −35.00 0.00 0.00 0 +0 2D-ROESY 155 w 2 H1M w 2 H4 0.00 1.40 −0.06 0.00 0.00 0 +2 2D-ROESY 142 g 4 H62 f′ 3 H2 0.00 0.88 −0.03 0.00 0.00 0 +0 2D-ROESY 121 g 4 H5 a′ 5 H1 0.00 0.68 −0.03 0.00 0.00 0 +0 2D-ROESY 149 g 4 H1M g 4 H4 0.00 1.40 −0.06 0.00 0.00 0 +2 2D-ROESY 123 g 4 H4 a′ 5 H1 0.00 0.14 0.01 0.00 0.00 0 +0 2D-NOESY 139 w 2 H61 f′ 3 H1 0.00 0.16 0.01 0.00 0.00 0 +0 2D-NOESY 125 a 6 H62 a′ 5 H2 0.00 1.70 −0.09 0.00 0.00 0 +0 2D-ROESY 143 g 4 H1 f′ 3 H2 0.00 1.10 −0.06 0.00 0.00 0 +0 2D-ROESY 161 w 2 H62 w′ 1 H2 0.00 0.59 −0.03 0.00 0.00 0 +0 2D-ROESY 124 a 6 H61 a′ 5 H2 0.00 1.20 −0.07 0.00 0.00 0 +0 2D-ROESY 120 w 2 H1 w 2 H2 0.55 0.35 0.58 0.00 0.00 0 +0 RDC 38 g 4 H1M g 4 H2N 9.40 3.80 9.30 0.00 0.00 0 +2 2D-NOESY 153 f′ 3 H2 g 4 H1 0.00 0.31 0.02 0.00 0.00 0 +0 2D-NOESY 108 a 6 H62 a 6 H2 0.00 1.80 −0.13 0.01 0.00 0 +0 2D-ROESY 137 g 4 H62 f′ 3 H1 0.00 0.27 0.02 0.01 0.00 0 +0 2D-NOESY 147 g 4 H1 f′ 3 H2 0.00 0.26 0.02 0.01 0.00 0 +0 2D-NOESY 124 g 4 H5 a′ 5 H1 0.00 0.13 0.01 0.01 0.00 0 +0 2D-NOESY 29 f′ 3 H1 f′ 3 H1 620.00 310.00 600.00 0.01 0.00 0 +0 2D-ROESY 102 a′ 5 H2 a 6 H1 0.00 0.57 −0.05 0.01 0.00 0 +0 2D-ROESY 31 f′ 3 H3 f′ 3 H1 −22.00 11.00 −23.00 0.01 0.00 0 +0 2D-ROESY 163 w 2 H1 w′ 1 H2 0.00 0.63 −0.06 0.01 0.00 0 +0 2D-ROESY 127 a 6 H61 a′ 5 H2 0.00 0.29 0.03 0.01 0.00 0 +0 2D-NOESY 40 g 4 H2N g 4 H2N 190.00 74.00 190.00 0.01 0.00 0 +0 2D-NOESY 122 w 2 H3 w 2 H2 1.20 0.35 1.10 0.01 0.00 0 +1 RDC 101 a′ 5 H2 a 6 H1 0.00 0.14 0.01 0.01 0.00 0 +0 2D-NOESY 127 w′ 1 H5 w′ 1 H4 −0.15 0.35 −0.11 0.01 0.01 0 +0 RDC 126 g 4 H1M a′ 5 H2 0.00 0.10 0.01 0.01 0.00 0 +2 2D-NOESY 57 w 2 H1M w 2 H2N 8.90 3.60 9.20 0.01 0.01 0 +2 2D-NOESY 160 f′ 3 H4 g 4 H2N 0.00 0.20 0.02 0.01 0.00 0 +0 2D-NOESY 145 g 4 H61 f′ 3 H2 0.00 0.09 0.01 0.01 0.00 0 +0 2D-NOESY 154 f′ 3 H3 g 4 H1 0.00 0.13 0.02 0.02 0.00 0 +0 2D-NOESY 141 w 2 H62 f′ 3 H2 0.00 0.88 −0.11 0.02 0.01 0 +0 2D-ROESY 116 g 4 H1M a′ 5 H1 0.00 0.12 0.01 0.02 0.01 0 +2 2D-NOESY 136 g 4 H61 f′ 3 H1 0.00 0.16 0.02 0.02 0.01 0 +0 2D-NOESY 8 a 6 H2 a 6 H4 −37.00 19.00 −35.00 0.02 0.01 0 +0 2D-ROESY 119 a 6 H61 a′ 5 H1 0.00 0.09 0.01 0.02 0.01 0 +0 2D-NOESY 122 g 4 H2 a′ 5 H1 0.00 0.14 0.02 0.02 0.01 0 +0 2D-NOESY 11 a′ 5 C4 a′ 5 H4 4.00 0.35 4.10 0.02 0.04 0 +0 RDC 120 a 6 H62 a′ 5 H1 0.00 0.09 0.01 0.02 0.01 0 +0 2D-NOESY 128 a 6 H62 a′ 5 H2 0.00 0.22 0.03 0.02 0.01 0 +0 2D-NOESY 107 a′ 5 H2 a′ 5 H1 1.10 0.35 0.94 0.03 0.01 0 +1 RDC 135 g 4 H5 f′ 3 H1 0.00 1.20 0.19 0.03 0.01 0 +0 2D-NOESY 110 a′ 5 H3 a 6 H2 0.00 0.14 0.02 0.03 0.01 0 +0 2D-NOESY 127 a 6 H1 a′ 5 H2 0.00 0.32 −0.05 0.03 0.01 0 +0 2D-ROESY 14 g 4 C3 g 4 H3 4.40 0.35 4.50 0.03 0.03 0 +0 RDC 116 f′ 3 H2 f′ 3 H1 1.00 0.35 0.84 0.03 0.02 0 +1 RDC 185 w′ 1 H4 w′ 1 H1 0.00 2.80 0.48 0.03 0.01 0 +0 2D-NOESY 41 w′ 1 H3 w′ 1 H1 −29.00 14.00 −31.00 0.03 0.02 0 +0 2D-ROESY 1 a 6 H1M a 6 H2N −17.00 3.40 −17.00 0.03 0.03 0 +2 15N-ROESY-HSQC 71 w 2 H1M w 2 H1 0.27 0.11 0.29 0.03 0.03 0 +2 2D-NOESY 166 g 4 H1M g 4 H62 0.00 0.04 0.01 0.04 0.02 0 +2 2D-NOESY 190 w 2 H1M w′ 1 H2 0.00 0.64 0.12 0.04 0.02 0 +2 2D-NOESY 126 g 4 H62 a′ 5 H2 0.00 0.54 −0.10 0.04 0.03 0 +0 2D-ROESY 184 w 2 H1M w 2 H62 0.00 0.04 0.01 0.04 0.02 0 +2 2D-NOESY 22 w 2 C1 w 2 H1 4.60 0.35 4.50 0.04 0.05 0 +0 RDC 129 g 4 H62 a′ 5 H2 0.00 0.22 0.04 0.04 0.03 0 +0 2D-NOESY 132 g 4 H4 f′ 3 H1 0.00 3.40 −0.66 0.04 0.03 0 +0 2D-ROESY 108 a′ 5 H3 a′ 5 H2 1.30 0.35 1.10 0.04 0.03 0 +1 RDC 125 w′ 1 H3 w′ 1 H2 0.59 0.35 0.80 0.04 0.03 0 +1 RDC 129 a 6 H1 a 6 H2 0.90 0.35 0.76 0.04 0.04 0 +0 RDC 132 w 2 H2N w 2 N2 −1.30 0.35 −1.20 0.04 0.06 0 +0 RDC 102 a′ 5 H3 a 6 H1 0.00 0.03 0.01 0.04 0.04 0 +0 2D-NOESY 106 a′ 5 H1 a 6 H1 0.00 0.80 −0.17 0.05 0.04 0 +0 2D-ROESY 7 a′ 5 H2 a 6 H2N 0.09 0.05 0.08 0.05 0.06 0 +0 2D-NOESY 85 a 6 H1M a 6 H2 0.40 0.17 0.44 0.05 0.06 0 +2 2D-NOESY 109 a 6 H5 a 6 H2 0.00 6.60 −1.60 0.06 0.07 0 +0 2D-ROESY 178 w′ 1 H4 w 2 H2N 0.00 0.10 0.02 0.06 0.07 0 +0 2D-NOESY 188 w 2 H61 w′ 1 H1 0.00 0.10 0.03 0.06 0.08 0 +0 2D-NOESY 133 g 4 H5 f′ 3 H1 0.00 0.95 0.23 0.06 0.09 0 +0 2D-ROESY 12 g 4 C1 g 4 H1 4.10 0.35 4.40 0.07 0.12 0 +0 RDC 191 w 2 H62 w′ 1 H2 0.00 0.05 0.01 0.07 0.09 0 +0 2D-NOESY 81 w′ 1 H2 w′ 1 H2 270.00 110.00 240.00 0.07 0.09 0 +0 2D-NOESY 58 w 2 H1 w 2 H2N 3.70 1.50 4.10 0.07 0.13 0 +0 2D-NOESY 105 a 6 H61 a 6 H1 0.00 0.92 −0.24 0.07 0.09 0 +0 2D-ROESY 104 a 6 H61 a 6 H1 0.00 0.35 0.09 0.07 0.09 0 +0 2D-NOESY 112 g 4 H3 g 4 H2 1.40 0.35 1.10 0.07 0.11 0 +1 RDC 128 a 6 H2 a′ 5 H2 0.00 1.30 −0.36 0.07 0.10 0 +0 2D-ROESY 39 g 4 H1 g 4 H2N 3.70 1.50 4.10 0.07 0.14 0 +0 2D-NOESY 51 f′ 3 H4 w 2 H1 −47.00 23.00 −41.00 0.08 0.17 0 +0 2D-ROESY 113 g 4 H4 g 4 H3 1.60 0.35 1.30 0.08 0.11 0 +1 RDC 162 a′ 5 H3 g 4 H2N 0.00 0.17 0.05 0.08 0.12 0 +0 2D-NOESY 47 g 4 H1 g 4 H1 220.00 87.00 190.00 0.08 0.13 0 +0 2D-NOESY 15 a 6 H1M a′ 5 H1 −3.90 1.90 −3.40 0.08 0.25 0 +2 2D-ROESY 31 g 4 H1M f′ 3 H1 1.10 0.44 1.00 0.08 0.28 0 +2 2D-NOESY 21 f′ 3 C5 f′ 3 H5 3.60 0.35 3.80 0.09 0.36 0 +0 RDC 101 a 6 H2 a 6 H1 0.10 0.35 −0.06 0.09 0.15 0 +1 RDC 19 a′ 5 H1 a′ 5 H1 570.00 290.00 660.00 0.09 0.16 0 +0 2D-ROESY 8 w 2 H1M w 2 H2N 94.00 38.00 82.00 0.09 0.16 0 +2 15N-NOESY-HSQC 119 f′ 3 H5 f′ 3 H4 −0.02 0.35 0.11 0.09 0.21 0 +0 RDC 128 a 6 H2N a 6 H2 0.10 0.35 0.31 0.10 0.20 0 +0 RDC 121 g 4 H2N a′ 5 H1 0.00 0.04 0.01 0.10 0.18 0 +0 2D-NOESY 35 f′ 3 H2 f′ 3 H2 270.00 110.00 240.00 0.10 0.20 0 +0 2D-NOESY 175 w 2 H61 w 2 H2N 0.00 0.07 0.02 0.10 0.18 0 +0 2D-NOESY 147 f′ 3 H2 g 4 H1 0.00 0.18 −0.06 0.10 0.19 0 +0 2D-ROESY 24 w 2 C3 w 2 H3 5.00 0.35 4.60 0.10 0.29 0 +0 RDC 153 w′ 1 H2 w 2 H1 0.00 0.18 −0.06 0.10 0.20 0 +0 2D-ROESY 146 g 4 H62 f′ 3 H2 0.00 0.04 0.01 0.11 0.23 0 +0 2D-NOESY 48 g 4 H2N g 4 H1 4.70 1.90 4.10 0.11 0.26 0 +0 2D-NOESY 61 w 2 H4 w 2 H2N 0.21 0.09 0.18 0.12 0.28 0 +0 2D-NOESY 187 w 2 H5 w′ 1 H1 0.00 0.69 0.24 0.12 0.28 0 +0 2D-NOESY 112 a′ 5 H2 a 6 H2 0.00 1.00 −0.36 0.12 0.29 0 +0 2D-ROESY 183 w 2 H1M w 2 H61 0.00 0.02 0.01 0.12 0.26 0 +2 2D-NOESY 165 g 4 H1M g 4 H61 0.00 0.02 0.01 0.12 0.26 0 +2 2D-NOESY 25 a′ 5 H2 a′ 5 H2 270.00 110.00 230.00 0.13 0.32 0 +0 2D-NOESY 31 w′ 1 C5 w′ 1 H5 2.10 0.35 1.90 0.13 1.30 0 +0 RDC 1 a 6 C1 a 6 H1 −5.80 0.35 −5.90 0.13 0.66 0 +0 RDC 74 w′ 1 H1 w′ 1 H1 310.00 120.00 270.00 0.13 0.32 0 +0 2D-NOESY 118 a 6 H5 a′ 5 H1 0.00 0.23 0.08 0.13 0.31 0 +0 2D-NOESY 44 g 4 H5 g 4 H1 −74.00 37.00 −60.00 0.13 0.31 0 +1 2D-ROESY 24 a′ 5 H2 a′ 5 H2 640.00 330.00 760.00 0.14 0.36 0 +0 2D-ROESY 40 w′ 1 H2 w′ 1 H2 670.00 330.00 790.00 0.14 0.37 0 +0 2D-ROESY 102 a 6 H3 a 6 H2 −1.00 0.35 −0.70 0.14 0.39 0 +1 RDC 168 w′ 1 H2 w 2 H1 0.00 0.06 0.02 0.14 0.35 0 +0 2D-NOESY 148 g 4 H1M f′ 3 H4 0.00 0.09 0.03 0.15 0.48 0 +2 2D-NOESY 189 w 2 H62 w′ 1 H1 0.00 0.07 0.03 0.15 0.42 0 +0 2D-NOESY 29 w′ 1 C3 w′ 1 H3 2.40 0.35 2.20 0.15 1.20 0 +0 RDC 118 f′ 3 H4 f′ 3 H3 0.35 0.35 0.66 0.15 0.49 0 +1 RDC 76 w 2 H1M w′ 1 H1 1.10 0.44 1.20 0.17 1.60 0 +2 2D-NOESY 6 a′ 5 H1 a 6 H2N 2.60 1.00 2.70 0.17 2.90 0 +0 2D-NOESY 3 a 6 H2 a 6 H2N −8.90 1.80 −8.10 0.19 0.88 0 +0 15N-ROESY-HSQC 157 g 4 H61 g 4 H2N 0.00 0.05 0.02 0.19 0.68 0 +0 2D-NOESY 162 w 2 H4 w′ 1 H2 0.00 2.00 −0.85 0.19 0.73 0 +0 2D-ROESY 105 a 6 H62 a 6 H61 −3.20 0.35 −2.90 0.19 1.80 0 +1 RDC 42 g 4 H4 g 4 H2N 0.22 0.09 0.18 0.20 0.78 0 +0 2D-NOESY 129 a 6 H4 a′ 5 H2 0.00 3.90 −1.80 0.21 0.84 0 +0 2D-ROESY 28 a′ 5 H5 a′ 5 H1 −44.00 22.00 −34.00 0.21 0.85 0 +0 2D-ROESY 109 a′ 5 H5 a 6 H2 0.00 0.08 0.04 0.22 0.92 0 +0 2D-NOESY 192 w 2 H4 w′ 1 H2 0.00 0.34 0.16 0.22 0.94 0 +0 2D-NOESY 2 a 6 H3 a 6 H2N 34.00 14.00 41.00 0.23 1.00 0 +0 15N-NOESY-HSQC 17 g 4 H1 g 4 H2N −15.00 3.10 −14.00 0.23 1.30 0 +0 15N-ROESY-HSQC 5 a 6 C6 a 6 H61 −1.30 0.35 −1.50 0.23 2.00 0 +0 RDC 13 a 6 H5 a 6 H1 0.72 0.29 0.58 0.23 1.00 0 +0 2D-NOESY 42 g 4 H1 g 4 H1 1500.00 750.00 1100.00 0.24 1.10 0 +1 2D-ROESY 20 a′ 5 H1 a′ 5 H3 −34.00 17.00 −26.00 0.24 1.10 0 +0 2D-ROESY 23 w 2 C2 w 2 H2 5.20 0.35 4.70 0.24 1.40 0 +0 RDC 27 a′ 5 H4 a′ 5 H2 −27.00 14.00 −34.00 0.24 1.10 0 +0 2D-ROESY 44 f′ 3 H1 g 4 H2N 4.90 1.90 4.00 0.25 2.20 0 +0 2D-NOESY 12 w 2 H2N w 2 H2N 440.00 88.00 400.00 0.25 1.40 0 +0 15N-ROESY-HSQC 123 w′ 1 H1 w′ 1 H2 0.17 0.35 −0.08 0.25 1.30 0 +0 RDC 17 f′ 3 C1 f′ 3 H1 3.10 0.35 3.50 0.25 1.90 0 +0 RDC 2 3J 4 H2 3J 4 H2N 9.80 0.50 9.90 0.25 3.70 1 +0 JCOUP 2 a 6 H1 a 6 H2N 1.40 0.55 1.60 0.26 1.50 0 +0 2D-NOESY 53 g 4 H1M g 4 H1 0.37 0.15 0.29 0.26 1.30 0 +2 2D-NOESY 79 w′ 1 H1 w 2 H4 0.32 0.13 0.26 0.26 1.40 0 +0 2D-NOESY 132 a 6 H1M a′ 5 H2 0.00 0.10 0.05 0.26 1.30 0 +2 2D-NOESY 152 f′ 3 H1 g 4 H1 0.00 0.53 0.27 0.26 1.30 0 +0 2D-NOESY 161 a′ 5 H2 g 4 H2N 0.00 0.04 0.02 0.28 1.50 0 +0 2D-NOESY 179 f′ 3 H2 w 2 H2N 0.00 0.04 0.02 0.29 1.70 0 +0 2D-NOESY 14 g 4 H3 g 4 H2N −14.00 2.80 −12.00 0.30 2.10 0 +2 15N-ROESY-HSQC 158 g 4 H62 g 4 H2N 0.00 0.04 0.02 0.30 1.80 0 +0 2D-NOESY 126 w′ 1 H4 w′ 1 H3 −0.37 0.35 0.06 0.30 1.80 0 +1 RDC 193 w 2 H1 w′ 1 H2 0.00 0.04 0.02 0.30 1.80 0 +0 2D-NOESY 176 w 2 H62 w 2 H2N 0.00 0.04 0.02 0.31 1.80 0 +0 2D-NOESY 59 w 2 H2N w 2 H2N 250.00 100.00 190.00 0.31 1.90 0 +0 2D-NOESY 6 a 6 H2N a 6 H2N 1900.00 770.00 2400.00 0.31 1.90 0 +0 15N-NOESY-HSQC 43 g 4 H1 g 4 H5 −85.00 43.00 −60.00 0.32 2.00 0 +1 2D-ROESY 27 w′ 1 C1 w′ 1 H1 1.40 0.35 1.80 0.33 2.90 0 +0 RDC 109 a′ 5 H4 a′ 5 H3 1.40 0.35 0.88 0.33 2.10 0 +1 RDC 25 a′ 5 H3 a′ 5 H1 −20.00 9.90 −26.00 0.36 2.50 0 +0 2D-ROESY 181 w 2 H1M w 2 H4 0.00 0.08 0.05 0.36 2.40 0 +2 2D-NOESY 18 g 4 H2N g 4 H2N 350.00 70.00 390.00 0.37 3.20 0 +0 15N-ROESY-HSQC 25 w 2 C4 w 2 H4 5.30 0.35 4.70 0.37 3.00 0 +0 RDC 15 g 4 C4 g 4 H4 5.40 0.35 4.70 0.37 2.90 0 +0 RDC 19 a′ 5 H3 a′ 5 H1 6.50 2.60 4.90 0.38 2.80 0 +0 2D-NOESY 13 g 4 H1M g 4 H2N −18.00 3.60 −16.00 0.38 3.10 0 +2 15N-ROESY-HSQC 8 a′ 5 C1 a′ 5 H1 4.40 0.35 3.80 0.38 3.20 0 +0 RDC 19 g 4 H2N g 4 H2N 3000.00 1200.00 2200.00 0.38 2.80 0 +0 15N-NOESY-HSQC 167 w′ 1 H1 w 2 H1 0.00 0.54 0.33 0.38 2.70 0 +0 2D-NOESY 164 g 4 H1M g 4 H5 0.00 0.06 0.04 0.39 2.90 0 +2 2D-NOESY 149 w 2 H1M f′ 3 H4 0.00 0.11 0.07 0.40 3.20 0 +2 2D-NOESY 18 a′ 5 H1 a′ 5 H1 280.00 110.00 210.00 0.40 3.10 0 +0 2D-NOESY 115 f′ 3 H1 f′ 3 H2 −0.19 0.35 0.07 0.41 3.30 0 +0 RDC 66 w 2 H1 w 2 H1 260.00 100.00 190.00 0.42 3.50 0 +0 2D-NOESY 5 a 6 H1 a 6 H5 −4.60 2.30 −3.10 0.43 3.50 0 +0 2D-ROESY 8 a′ 5 H3 a 6 H2N 0.14 0.07 0.09 0.44 4.00 0 +0 2D-NOESY 19 f′ 3 C3 f′ 3 H3 4.60 0.35 4.10 0.46 5.50 0 +0 RDC 5 a 6 H1 a 6 H2N 22.00 9.00 16.00 0.47 4.20 0 +0 15N-NOESY-HSQC 28 w′ 1 C2 w′ 1 H2 2.60 0.35 2.10 0.47 6.40 0 +0 RDC 13 g 4 C2 g 4 H2 5.40 0.35 4.60 0.48 4.80 0 +0 RDC 106 a′ 5 H1 a′ 5 H2 0.78 0.35 0.38 0.49 4.90 0 +0 RDC 36 f′ 3 H4 f′ 3 H2 8.80 3.50 6.30 0.49 4.70 0 +0 2D-NOESY 15 a 6 H2 a 6 H2 300.00 120.00 220.00 0.49 4.70 0 +0 2D-NOESY 130 a 6 H2 a′ 5 H2 0.00 0.12 0.09 0.50 4.90 0 +0 2D-NOESY 1 3J 2 H2 3J 2 H2N 9.70 0.50 9.90 0.52 12.00 1 +0 JCOUP 10 w 2 H2 w 2 H2N 30.00 12.00 22.00 0.52 5.20 0 +0 15N-NOESY-HSQC 2 g 4 H2N g 4 N2 0.57 0.01 0.57 0.52 15.00 0 +0 ORDER 16 f′ 3 H1 g 4 H2N −12.00 2.50 −13.00 0.53 10.00 0 +0 15N-ROESY-HSQC 83 a′ 5 H3 g 4 H1 0.35 0.14 0.25 0.55 6.70 0 +0 2D-NOESY 58 w 2 H1M w′ 1 H1 −4.70 2.40 −3.00 0.55 6.70 0 +2 2D-ROESY 22 a′ 5 H1 a′ 5 H5 −24.00 13.00 −34.00 0.55 5.80 0 +0 2D-ROESY 32 f′ 3 H4 f′ 3 H2 −25.00 13.00 −35.00 0.57 6.20 0 +0 2D-ROESY 172 w 2 H61 w 2 H1 0.00 0.31 0.24 0.58 6.30 0 +0 2D-NOESY 4 a′ 5 H1 a 6 H2N −9.50 1.90 −9.80 0.58 30.00 0 +0 15N-ROESY-HSQC 3 a 6 H2N a 6 N2 0.51 0.02 0.50 0.58 18.00 0 +0 ORDER 63 w′ 1 H1 w 2 H2N 5.90 2.40 4.20 0.59 7.90 0 +0 2D-NOESY 1 w 2 H2N w 2 N2 0.44 0.01 0.44 0.59 27.00 0 +0 ORDER 14 g 4 H1M g 4 H2N 120.00 48.00 83.00 0.60 6.90 0 +2 15N-NOESY-HSQC 134 g 4 H4 f′ 3 H1 0.00 0.27 0.21 0.61 7.20 0 +0 2D-NOESY 41 g 4 H3 g 4 H2N 5.80 2.30 4.00 0.63 7.60 0 +2 2D-NOESY 55 g 4 H1M f′ 3 H3 0.91 0.37 0.81 0.64 20.00 0 +2 2D-NOESY 84 a 6 H1M a 6 H1 0.40 0.16 0.27 0.64 7.90 0 +2 2D-NOESY 9 a′ 5 H5 a 6 H2N 0.31 0.13 0.40 0.65 16.00 0 +0 2D-NOESY 50 f′ 3 H1 f′ 3 H3 −39.00 19.00 −23.00 0.67 8.60 0 +0 2D-ROESY 186 w 2 H4 w′ 1 H1 0.00 0.31 0.26 0.68 8.80 0 +0 2D-NOESY 106 a 6 H61 a 6 H2 0.00 0.12 0.10 0.68 8.70 0 +0 2D-NOESY 43 g 4 H5 g 4 H2N 0.40 0.16 0.27 0.69 9.10 0 +0 2D-NOESY 75 w′ 1 H3 w′ 1 H1 8.20 3.30 5.40 0.74 10.00 0 +0 2D-NOESY 143 w 2 H61 f′ 3 H2 0.00 0.09 0.08 0.75 11.00 0 +0 2D-NOESY 18 f′ 3 C2 f′ 3 H2 4.60 0.35 4.00 0.76 14.00 0 +0 RDC 151 g 4 H61 g 4 H1 0.00 0.26 0.23 0.78 12.00 0 +0 2D-NOESY 133 g 4 H2N g 4 N2 −1.80 0.35 −1.20 0.79 13.00 0 +0 RDC 124 w′ 1 H2 w′ 1 H1 −0.37 0.35 0.55 0.80 12.00 0 +1 RDC 114 g 4 H62 g 4 H5 −3.40 0.35 −2.30 0.81 16.00 0 +1 RDC 29 f′ 3 H1 f′ 3 H1 310.00 120.00 200.00 0.84 13.00 0 +0 2D-NOESY 23 a′ 5 H2 a 6 H3 −5.60 2.80 −3.10 0.84 14.00 0 +0 2D-ROESY 50 g 4 H5 g 4 H1 9.60 3.80 6.10 0.84 14.00 0 +0 2D-NOESY 2 a 6 H3 a 6 H2N −13.00 2.60 −15.00 0.85 15.00 0 +0 15N-ROESY-HSQC 13 w 2 H2N w 2 H2N 3600.00 1400.00 2200.00 0.86 14.00 0 +0 15N-NOESY-HSQC 30 f′ 3 H2 f′ 3 H2 520.00 270.00 770.00 0.87 14.00 0 +0 2D-ROESY 60 w 2 H3 w 2 H2N 6.40 2.60 4.00 0.88 15.00 0 +2 2D-NOESY 182 w 2 H1M w 2 H5 0.00 0.04 0.04 0.89 15.00 0 +2 2D-NOESY 54 g 4 H1 a′ 5 H4 −27.00 14.00 −40.00 0.92 18.00 0 +0 2D-ROESY 12 a 6 H4 a 6 H1 0.69 0.28 0.42 0.95 17.00 0 +0 2D-NOESY 16 g 4 H2 g 4 H2N 35.00 14.00 21.00 0.96 18.00 0 +0 15N-NOESY-HSQC 62 w 2 H5 w 2 H2N 0.45 0.18 0.27 0.97 18.00 0 +0 2D-NOESY 112 a 6 H61 a 6 H2N 0.00 0.02 0.02 0.98 18.00 0 +0 2D-NOESY 150 g 4 H4 g 4 H1 0.00 0.43 0.43 0.98 18.00 0 +0 2D-NOESY 26 a′ 5 H4 a′ 5 H2 10.00 4.00 6.10 0.98 18.00 0 +0 2D-NOESY 78 w 2 H3 w′ 1 H1 26.00 10.00 16.00 0.98 19.00 0 +1 2D-NOESY 148 a′ 5 H3 g 4 H1 0.00 0.83 −0.82 0.98 19.00 0 +0 2D-ROESY 131 a 6 H2N a 6 N2 0.82 0.35 0.20 1.00 22.00 0 +0 RDC 117 a 6 H4 a′ 5 H1 0.00 0.14 0.14 1.00 20.00 0 +0 2D-NOESY 52 a′ 5 H4 g 4 H1 −79.00 40.00 −40.00 1.00 20.00 0 +0 2D-ROESY 113 a 6 H62 a 6 H2N 0.00 0.02 0.02 1.10 23.00 0 +0 2D-NOESY 5 a 6 H1 a 6 H2N −5.10 1.00 −6.10 1.10 26.00 0 +0 15N-ROESY-HSQC 4 a 6 H1 a 6 H4 −2.10 1.10 −0.90 1.10 23.00 0 +0 2D-ROESY 156 g 4 H62 g 4 H1 0.00 0.17 0.18 1.10 22.00 0 +0 2D-NOESY 53 w 2 H1 f′ 3 H4 −27.00 14.00 −41.00 1.10 27.00 0 +0 2D-ROESY 114 a 6 H4 a′ 5 H1 0.00 0.55 −0.57 1.10 22.00 0 +0 2D-ROESY 57 g 4 H1M f′ 3 H1 −4.70 2.40 −2.20 1.20 27.00 0 +2 2D-ROESY 36 w 2 H1M w′ 1 H3 −3.80 1.90 −1.80 1.20 31.00 0 +2 2D-ROESY 10 a′ 5 C3 a′ 5 H3 5.20 0.35 4.10 1.20 27.00 0 +0 RDC 30 w′ 1 C4 w′ 1 H4 1.10 0.35 1.90 1.20 32.00 0 +0 RDC 10 a 6 H1 a 6 H1 420.00 170.00 240.00 1.20 27.00 0 +0 2D-NOESY 177 f′ 3 H3 w 2 H2N 0.00 0.04 0.05 1.30 33.00 0 +0 2D-NOESY 144 w 2 H62 f′ 3 H2 0.00 0.04 0.05 1.30 36.00 0 +0 2D-NOESY 2 a 6 H1 a 6 H2 −88.00 44.00 −38.00 1.30 32.00 0 +0 2D-ROESY 173 w 2 H62 w 2 H1 0.00 0.16 0.18 1.30 30.00 0 +0 2D-NOESY 68 w 2 H5 w 2 H1 12.00 4.60 6.20 1.30 34.00 0 +0 2D-NOESY 171 w 2 H4 w 2 H1 0.00 0.37 0.43 1.30 34.00 0 +0 2D-NOESY 14 a 6 H1 a 6 H2 12.00 5.00 6.40 1.40 40.00 0 +0 2D-NOESY 108 a 6 H5 a 6 H2 0.00 0.38 0.44 1.40 35.00 0 +0 2D-NOESY 130 a′ 5 H1 a′ 5 H2 1.10 0.35 0.38 1.40 38.00 0 +0 RDC 6 a 6 H2 a 6 H1 −92.00 46.00 −38.00 1.40 37.00 0 +0 2D-ROESY 73 w 2 H1M w′ 1 H3 0.57 0.23 0.76 1.40 92.00 0 +2 2D-NOESY 46 f′ 3 H1 g 4 H2 −9.50 4.70 −3.90 1.40 39.00 0 +1 2D-ROESY 12 w 2 H1 w 2 H2N 75.00 30.00 40.00 1.40 36.00 0 +0 15N-NOESY-HSQC 38 w′ 1 H1 w′ 1 H1 620.00 310.00 990.00 1.40 36.00 0 +0 2D-ROESY 105 a′ 5 H1 a 6 H1 0.00 0.05 0.06 1.40 38.00 0 +0 2D-NOESY 180 w 2 H1M w 2 H3 0.00 0.24 0.29 1.50 41.00 0 +2 2D-NOESY 77 w 2 H2 w′ 1 H1 0.91 0.37 0.46 1.50 43.00 0 +0 2D-NOESY 70 f′ 3 H2 w 2 H1 0.51 0.20 0.27 1.50 43.00 0 +0 2D-NOESY 7 a′ 5 H5 a 6 H2N 7.90 3.30 3.90 1.50 46.00 0 +0 15N-NOESY-HSQC 9 a′ 5 C2 a′ 5 H2 5.30 0.35 4.10 1.60 53.00 0 +0 RDC 8 w 2 H3 w 2 H2N −16.00 3.30 −12.00 1.60 47.00 0 +2 15N-ROESY-HSQC 45 f′ 3 H2 g 4 H2N 0.19 0.08 0.09 1.60 48.00 0 +0 2D-NOESY 45 g 4 H2 f′ 3 H1 −11.00 5.30 −3.90 1.60 50.00 0 +1 2D-ROESY 69 f′ 3 H4 w 2 H1 16.00 6.20 7.80 1.60 47.00 0 +0 2D-NOESY 11 w 2 H1 w 2 H2N −19.00 3.70 −14.00 1.70 58.00 0 +0 15N-ROESY-HSQC 64 w′ 1 H2 w 2 H2N 0.20 0.08 0.10 1.70 57.00 0 +0 2D-NOESY 7 a 6 H2 a 6 H2 2000.00 1000.00 690.00 1.70 55.00 0 +0 2D-ROESY 33 g 4 H3 f′ 3 H1 26.00 10.00 12.00 1.70 55.00 0 +1 2D-NOESY 1 a 6 H1 a 6 H1 2400.00 1200.00 820.00 1.70 56.00 0 +0 2D-ROESY 49 g 4 H1 a′ 5 H3 −2.90 1.60 −0.82 1.70 54.00 0 +0 2D-ROESY 12 a 6 H1M a 6 H1 −1.80 0.91 −0.60 1.70 55.00 0 +2 2D-ROESY 10 w′ 1 H1 w 2 H2N −13.00 2.60 −16.00 1.70 82.00 0 +0 15N-ROESY-HSQC 15 g 4 H2 g 4 H2N −11.00 2.10 −7.90 1.70 59.00 0 +0 15N-ROESY-HSQC 110 g 4 H1 g 4 H2 −0.36 0.35 0.54 1.80 61.00 0 +0 RDC 32 g 4 H2 f′ 3 H1 0.91 0.37 0.42 1.80 63.00 0 +0 2D-NOESY 59 g 4 H1M g 4 H1 −1.30 0.65 −0.42 1.80 60.00 0 +2 2D-ROESY 60 w 2 H1M w 2 H1 −1.30 0.65 −0.41 1.80 63.00 0 +2 2D-ROESY 65 w′ 1 H3 w 2 H2N 0.34 0.14 0.15 1.90 68.00 0 +0 2D-NOESY 4 a′ 5 H1 a 6 H2N 59.00 24.00 27.00 1.90 71.00 0 +0 15N-NOESY-HSQC 30 f′ 3 H3 f′ 3 H1 9.80 3.90 4.50 1.90 66.00 0 +0 2D-NOESY 134 a 6 H2N a 6 N2 1.10 0.35 0.20 1.90 76.00 0 +0 RDC 10 a 6 H3 a′ 5 H1 −37.00 18.00 −12.00 1.90 67.00 0 +0 2D-ROESY 18 g 4 H1 g 4 H2N 90.00 36.00 40.00 1.90 70.00 0 +0 15N-NOESY-HSQC 51 a′ 5 H4 g 4 H1 17.00 6.80 7.50 2.00 74.00 0 +0 2D-NOESY 6 a 6 H2N a 6 H2N 330.00 66.00 430.00 2.00 77.00 0 +0 15N-ROESY-HSQC 114 a 6 H5 a 6 H2N 0.00 0.15 0.21 2.00 74.00 0 +0 2D-NOESY 111 a′ 5 H2 a 6 H2 0.00 0.06 0.09 2.00 78.00 0 +0 2D-NOESY 3 3J 6 H2 3J 6 H2N 9.40 0.50 10.00 2.00 82.00 1 +0 JCOUP 55 g 4 H1 g 4 H3 −14.00 8.20 −26.00 2.00 74.00 0 +2 2D-ROESY 3 a 6 C3 a 6 H3 −1.10 0.35 −0.31 2.00 88.00 0 +0 RDC 34 w 2 H4 w′ 1 H1 −3.10 1.50 −0.89 2.00 76.00 0 +0 2D-ROESY 46 f′ 3 H3 g 4 H2N 0.33 0.13 0.14 2.10 82.00 0 +0 2D-NOESY 56 w 2 H1 w 2 H3 −14.00 8.20 −26.00 2.10 89.00 0 +2 2D-ROESY 47 f′ 3 H3 w 2 H1 −4.10 2.30 −0.78 2.10 85.00 0 +0 2D-ROESY 3 a 6 H1 a 6 H3 −11.00 5.40 −2.70 2.10 84.00 0 +0 2D-ROESY 27 a 6 H3 a′ 5 H2 1.30 0.53 0.56 2.10 83.00 0 +0 2D-NOESY 72 w 2 H1M w 2 H2 1.00 0.42 0.42 2.20 88.00 0 +2 2D-NOESY 56 g 4 H1M g 4 H2 1.00 0.41 0.42 2.20 91.00 0 +2 2D-NOESY 16 a′ 5 H1 a 6 H2 −5.50 2.80 −1.40 2.20 95.00 0 +0 2D-ROESY 67 w 2 H3 w 2 H1 14.00 5.40 5.40 2.20 95.00 0 +1 2D-NOESY 194 w 2 H1M w′ 1 H2 0.00 0.08 0.12 2.20 98.00 0 +2 2D-NOESY 49 g 4 H3 g 4 H1 13.00 5.10 5.20 2.20 89.00 0 +1 2D-NOESY 62 w 2 H1M w 2 H2 −4.20 2.10 −0.99 2.30 100.00 0 +2 2D-ROESY 7 w 2 H1M w 2 H2N −23.00 4.60 −16.00 2.30 100.00 0 +2 15N-ROESY-HSQC 11 a 6 H3 a 6 H1 1.40 0.56 0.56 2.30 100.00 0 +0 2D-NOESY 33 g 4 H1M f′ 3 H3 −7.80 3.90 −1.90 2.30 110.00 0 +2 2D-ROESY 61 g 4 H1M g 4 H2 −4.20 2.10 −0.99 2.30 100.00 0 +2 2D-ROESY 11 w′ 1 H1 w 2 H2N 110.00 44.00 41.00 2.40 110.00 0 +0 15N-NOESY-HSQC 174 f′ 3 H3 w 2 H1 0.00 0.16 0.25 2.40 110.00 0 +0 2D-NOESY 82 w′ 1 H5 w′ 1 H2 1.30 0.56 0.47 2.40 110.00 0 +0 2D-NOESY 107 a 6 H62 a 6 H2 0.00 0.11 0.17 2.40 110.00 0 +0 2D-NOESY 4 a 6 C5 a 6 H5 −1.20 0.35 −0.42 2.40 120.00 0 +0 RDC 48 a′ 5 H3 g 4 H1 −6.90 3.90 −0.82 2.50 120.00 0 +0 2D-ROESY 17 a′ 5 H1 a 6 H3 −57.00 28.00 −12.00 2.50 120.00 0 +0 2D-ROESY 37 w′ 1 H1 w 2 H4 −4.50 2.20 −0.89 2.50 120.00 0 +0 2D-ROESY 13 a 6 H1M a 6 H2 −4.90 2.50 −0.95 2.50 120.00 0 +2 2D-ROESY 14 a 6 H1M a 6 H3 −2.50 1.30 −0.46 2.50 120.00 0 +2 2D-ROESY 163 g 4 H1M g 4 H4 0.00 0.03 0.05 2.50 120.00 0 +2 2D-NOESY 17 f′ 3 H1 g 4 H2N 100.00 42.00 39.00 2.50 120.00 0 +0 15N-NOESY-HSQC 52 a′ 5 H2 g 4 H1 0.71 0.28 0.25 2.70 140.00 0 +0 2D-NOESY 22 a 6 H2 a′ 5 H1 0.85 0.34 0.30 2.70 130.00 0 +0 2D-NOESY 54 g 4 H1 a′ 5 H3 0.71 0.28 0.25 2.70 140.00 0 +0 2D-NOESY 131 a 6 H4 a′ 5 H2 0.00 0.20 0.33 2.70 140.00 0 +0 2D-NOESY 80 w 2 H1 f′ 3 H3 0.71 0.28 0.25 2.80 150.00 0 +0 2D-NOESY 15 g 4 H3 g 4 H2N 120.00 47.00 38.00 2.90 160.00 0 +2 15N-NOESY-HSQC 21 a′ 5 H1 a′ 5 H4 −18.00 9.90 −1.30 2.90 160.00 0 +0 2D-ROESY 9 w 2 H3 w 2 H2N 130.00 51.00 39.00 3.00 170.00 0 +2 15N-NOESY-HSQC 111 g 4 H2 g 4 H1 2.30 0.35 0.84 3.00 170.00 0 +1 RDC 37 w 2 H1 f′ 3 H2 0.91 0.37 0.27 3.00 170.00 0 +0 2D-NOESY 2 a 6 C2 a 6 H2 0.69 0.35 −0.26 3.10 210.00 0 +0 RDC 20 f′ 3 C4 f′ 3 H4 2.60 0.35 4.10 3.10 180.00 0 +0 RDC 21 a′ 5 H5 a′ 5 H1 21.00 8.40 6.30 3.10 180.00 0 +0 2D-NOESY 26 w 2 CME w 2 H1M −1.80 0.35 −3.70 3.20 200.00 0 +2 RDC 142 g 4 H1M f′ 3 H2 0.00 0.06 0.11 3.20 200.00 0 +2 2D-NOESY 18 a′ 5 H1 a 6 H4 −6.00 3.00 −0.57 3.20 190.00 0 +0 2D-ROESY 9 a 6 H2 a′ 5 H1 −13.00 6.50 −1.40 3.20 190.00 0 +0 2D-ROESY 121 w 2 H2 w 2 H1 2.50 0.35 0.92 3.20 190.00 0 +1 RDC 9 w 2 H2 w 2 H2N −12.00 2.50 −8.00 3.30 210.00 0 +0 15N-ROESY-HSQC 34 f′ 3 H1 g 4 H4 0.80 0.32 0.21 3.40 220.00 0 +0 2D-NOESY 26 a′ 5 H4 a′ 5 H1 −17.00 8.60 −1.30 3.40 220.00 0 +0 2D-ROESY 115 a′ 5 H4 a 6 H2N 0.00 0.02 0.04 3.50 250.00 0 +0 2D-NOESY 35 w 2 H1M w′ 1 H2 −4.00 2.00 −0.24 3.50 230.00 0 +2 2D-ROESY 3 a 6 H2 a 6 H2N 13.00 5.10 22.00 3.60 240.00 0 +0 15N-NOESY-HSQC 17 a′ 5 H1 a 6 H2 1.60 0.64 0.30 3.90 290.00 0 +0 2D-NOESY 20 a′ 5 H4 a′ 5 H1 2.00 0.80 0.43 3.90 280.00 0 +0 2D-NOESY 1 a 6 H1M a 6 H2N 49.00 20.00 88.00 3.90 290.00 0 +2 15N-NOESY-HSQC 28 g 4 H1 a′ 5 H2 1.20 0.48 0.25 3.90 290.00 0 +0 2D-NOESY 7 a 6 CME a 6 H1M −1.10 0.35 −3.30 3.90 290.00 0 +2 RDC 23 a 6 H3 a′ 5 H1 10.00 4.10 2.10 3.90 300.00 0 +0 2D-NOESY 5 a 6 H4 a 6 H2N 0.09 0.05 0.19 4.20 340.00 0 +0 2D-NOESY 3 a 6 H2N a 6 H2N 110.00 44.00 200.00 4.40 360.00 0 +0 2D-NOESY 103 a 6 H4 a 6 H3 3.10 0.35 0.80 4.90 450.00 0 +1 RDC 16 a 6 H4 a 6 H2 3.20 1.30 6.30 5.70 630.00 0 +0 2D-NOESY 4 a 6 H3 a 6 H2N 2.10 0.84 4.10 5.90 670.00 0 +0 2D-NOESY 16 g 4 CME g 4 H1M −1.60 0.35 −4.20 6.00 700.00 0 +2 RDC 6 a 6 C6 a 6 H62 −0.83 0.35 −2.20 6.00 760.00 0 +0 RDC 1 a 6 H1M a 6 H2N 4.80 1.90 9.80 7.00 940.00 0 +2 2D-NOESY 24 a 6 H1M a′ 5 H1 0.66 0.27 1.40 8.40 1500.00 0 +2 2D-NOESY 104 a 6 H5 a 6 H4 6.50 0.35 2.10 10.00 2000.00 0 +2 RDC

PDB Coordinate for the Final Optimized Mean Structure

ATOM 1 C1 BGLA 1 7.691 2.111 −7.763 0.00 0.00 MOLG ATOM 2 H1 BGLA 1 8.059 1.588 −6.861 0.00 0.00 MOLG ATOM 3 C5 BGLA 1 9.670 3.603 −7.779 0.00 0.00 MOLG ATOM 4 H5 BGLA 1 10.044 3.071 −6.900 0.00 0.00 MOLG ATOM 5 O5 BGLA 1 8.164 3.516 −7.763 0.00 0.00 MOLG ATOM 6 C2 BGLA 1 8.207 1.397 −9.039 0.00 0.00 MOLG ATOM 7 H2 BGLA 1 7.802 1.883 −9.931 0.00 0.00 MOLG ATOM 8 O2 BGLA 1 7.727 0.020 −8.989 0.00 0.00 MOLG ATOM 9 HO2 BGLA 1 6.766 0.035 −8.859 0.00 0.00 MOLG ATOM 10 C3 BGLA 1 9.760 1.421 −9.062 0.00 0.00 MOLG ATOM 11 H3 BGLA 1 10.170 0.891 −8.199 0.00 0.00 MOLG ATOM 12 O3 BGLA 1 10.285 0.826 −10.288 0.00 0.00 MOLG ATOM 13 HO3 BGLA 1 11.200 1.126 −10.344 0.00 0.00 MOLG ATOM 14 C4 BGLA 1 10.199 2.907 −9.055 0.00 0.00 MOLG ATOM 15 H4 BGLA 1 9.830 3.427 −9.944 0.00 0.00 MOLG ATOM 16 O4 BGLA 1 11.653 2.950 −9.050 0.00 0.00 MOLG ATOM 17 HO4 BGLA 1 11.900 3.778 −8.585 0.00 0.00 MOLG ATOM 18 C6 BGLA 1 10.281 5.059 −7.707 0.00 0.00 MOLG ATOM 19 O6A BGLA 1 9.961 6.060 −8.777 0.00 0.00 MOLG ATOM 20 O6B BGLA 1 11.179 5.440 −6.568 0.00 0.00 MOLG ATOM 21 C1 BNAG 2 3.985 2.018 −4.633 0.00 0.00 MOLG ATOM 22 H1 BNAG 2 4.770 2.300 −3.906 0.00 0.00 MOLG ATOM 23 C5 BNAG 2 4.039 4.308 −5.526 0.00 0.00 MOLG ATOM 24 H5 BNAG 2 4.800 4.573 −4.786 0.00 0.00 MOLG ATOM 25 O5 BNAG 2 3.182 3.221 −4.965 0.00 0.00 MOLG ATOM 26 C2 BNAG 2 4.680 1.479 −5.917 0.00 0.00 MOLG ATOM 27 H2 BNAG 2 3.914 1.224 −6.654 0.00 0.00 MOLG ATOM 28 N2 BNAG 2 5.432 0.253 −5.593 0.00 0.00 MOLG ATOM 29 H2N BNAG 2 6.154 0.353 −4.885 0.00 0.00 MOLG ATOM 30 C2N BNAG 2 5.210 −0.956 −6.161 0.00 0.00 MOLG ATOM 31 O2N BNAG 2 4.352 −1.117 −7.016 0.00 0.00 MOLG ATOM 32 CME BNAG 2 6.096 −2.120 −5.674 0.00 0.00 MOLG ATOM 33 H1M BNAG 2 6.665 −2.531 −6.516 0.00 0.00 MOLG ATOM 34 H2M BNAG 2 6.804 −1.776 −4.910 0.00 0.00 MOLG ATOM 35 H3M BNAG 2 5.464 −2.908 −5.253 0.00 0.00 MOLG ATOM 36 C3 BNAG 2 5.607 2.582 −6.488 0.00 0.00 MOLG ATOM 37 H3 BNAG 2 6.377 2.843 −5.755 0.00 0.00 MOLG ATOM 38 O3 BNAG 2 6.222 2.111 −7.763 0.00 0.00 MOLG ATOM 39 C4 BNAG 2 4.733 3.810 −6.818 0.00 0.00 MOLG ATOM 40 H4 BNAG 2 3.990 3.555 −7.579 0.00 0.00 MOLG ATOM 41 O4 BNAG 2 5.567 4.882 −7.313 0.00 0.00 MOLG ATOM 42 HO4 BNAG 2 6.342 4.516 −7.773 0.00 0.00 MOLG ATOM 43 C6 BNAG 2 3.148 5.542 −5.770 0.00 0.00 MOLG ATOM 44 H61 BNAG 2 2.698 5.885 −4.837 0.00 0.00 MOLG ATOM 45 H62 BNAG 2 3.745 6.358 −6.183 0.00 0.00 MOLG ATOM 46 O6 BNAG 2 2.094 5.219 −6.701 0.00 0.00 MOLG ATOM 47 HO6 BNAG 2 2.474 4.705 −7.423 0.00 0.00 MOLG ATOM 48 C1 BGLA 3 0.306 1.365 −0.794 0.00 0.00 MOLG ATOM 49 H1 BGLA 3 −0.326 0.548 −1.190 0.00 0.00 MOLG ATOM 50 C5 BGLA 3 2.356 0.358 −1.767 0.00 0.00 MOLG ATOM 51 H5 BGLA 3 1.730 −0.433 −2.191 0.00 0.00 MOLG ATOM 52 O5 BGLA 3 1.679 0.867 −0.520 0.00 0.00 MOLG ATOM 53 C2 BGLA 3 0.392 2.529 −1.819 0.00 0.00 MOLG ATOM 54 H2 BGLA 3 0.971 3.355 −1.399 0.00 0.00 MOLG ATOM 55 O2 BGLA 3 −0.967 2.987 −2.078 0.00 0.00 MOLG ATOM 56 HO2 BGLA 3 −1.370 3.241 −1.232 0.00 0.00 MOLG ATOM 57 C3 BGLA 3 1.038 2.028 −3.138 0.00 0.00 MOLG ATOM 58 H3 BGLA 3 0.438 1.234 −3.591 0.00 0.00 MOLG ATOM 59 O3 BGLA 3 1.222 3.105 −4.109 0.00 0.00 MOLG ATOM 60 HO3 BGLA 3 1.868 2.786 −4.752 0.00 0.00 MOLG ATOM 61 C4 BGLA 3 2.447 1.511 −2.784 0.00 0.00 MOLG ATOM 62 H4 BGLA 3 3.024 2.330 −2.341 0.00 0.00 MOLG ATOM 63 O4 BGLA 3 3.089 1.015 −4.032 0.00 0.00 MOLG ATOM 64 C6 BGLA 3 3.793 −0.260 −1.534 0.00 0.00 MOLG ATOM 65 O6A BGLA 3 4.048 −1.705 −1.844 0.00 0.00 MOLG ATOM 66 O6B BGLA 3 4.902 0.600 −1.002 0.00 0.00 MOLG ATOM 67 C1 BNAG 4 −2.406 −0.099 2.989 0.00 0.00 MOLG ATOM 68 H1 BNAG 4 −2.142 −1.113 2.632 0.00 0.00 MOLG ATOM 69 C5 BNAG 4 −0.124 0.167 3.874 0.00 0.00 MOLG ATOM 70 H5 BNAG 4 0.123 −0.842 3.529 0.00 0.00 MOLG ATOM 71 O5 BNAG 4 −1.584 0.226 4.180 0.00 0.00 MOLG ATOM 72 C2 BNAG 4 −2.103 0.920 1.852 0.00 0.00 MOLG ATOM 73 H2 BNAG 4 −2.342 1.927 2.204 0.00 0.00 MOLG ATOM 74 N2 BNAG 4 −2.964 0.628 0.691 0.00 0.00 MOLG ATOM 75 H2N BNAG 4 −2.865 −0.301 0.290 0.00 0.00 MOLG ATOM 76 C2N BNAG 4 −3.856 1.494 0.152 0.00 0.00 MOLG ATOM 77 O2N BNAG 4 −4.000 2.626 0.587 0.00 0.00 MOLG ATOM 78 CME BNAG 4 −4.681 0.977 −1.043 0.00 0.00 MOLG ATOM 79 H1M BNAG 4 −4.493 1.604 −1.922 0.00 0.00 MOLG ATOM 80 H2M BNAG 4 −4.410 −0.056 −1.287 0.00 0.00 MOLG ATOM 81 H3M BNAG 4 −5.747 1.023 −0.796 0.00 0.00 MOLG ATOM 82 C3 BNAG 4 −0.597 0.841 1.484 0.00 0.00 MOLG ATOM 83 H3 BNAG 4 −0.348 −0.162 1.121 0.00 0.00 MOLG ATOM 84 O3 BNAG 4 −0.271 1.874 0.459 0.00 0.00 MOLG ATOM 85 C4 BNAG 4 0.211 1.184 2.755 0.00 0.00 MOLG ATOM 86 H4 BNAG 4 −0.020 2.201 3.085 0.00 0.00 MOLG ATOM 87 O4 BNAG 4 1.625 1.096 2.466 0.00 0.00 MOLG ATOM 88 HO4 BNAG 4 1.773 1.326 1.532 0.00 0.00 MOLG ATOM 89 C6 BNAG 4 0.670 0.451 5.166 0.00 0.00 MOLG ATOM 90 H61 BNAG 4 0.430 −0.290 5.932 0.00 0.00 MOLG ATOM 91 H62 BNAG 4 1.743 0.397 4.969 0.00 0.00 MOLG ATOM 92 O6 BNAG 4 0.353 1.756 5.691 0.00 0.00 MOLG ATOM 93 HO6 BNAG 4 0.844 1.897 6.502 0.00 0.00 MOLG ATOM 94 C1 BGLA 5 −5.910 −1.910 6.615 0.00 0.00 MOLG ATOM 95 H1 BGLA 5 −6.670 −1.107 6.607 0.00 0.00 MOLG ATOM 96 C5 BGLA 5 −5.539 −1.635 4.179 0.00 0.00 MOLG ATOM 97 H5 BGLA 5 −6.272 −0.822 4.188 0.00 0.00 MOLG ATOM 98 O5 BGLA 5 −5.887 −2.588 5.296 0.00 0.00 MOLG ATOM 99 C2 BGLA 5 −4.510 −1.312 6.898 0.00 0.00 MOLG ATOM 100 H2 BGLA 5 −3.762 −2.109 6.944 0.00 0.00 MOLG ATOM 101 O2 BGLA 5 −4.531 −0.610 8.177 0.00 0.00 MOLG ATOM 102 HO2 BGLA 5 −3.722 −0.085 8.188 0.00 0.00 MOLG ATOM 103 C3 BGLA 5 −4.139 −0.290 5.798 0.00 0.00 MOLG ATOM 104 H3 BGLA 5 −4.857 0.536 5.774 0.00 0.00 MOLG ATOM 105 O3 BGLA 5 −2.803 0.244 6.051 0.00 0.00 MOLG ATOM 106 HO3 BGLA 5 −2.411 0.507 5.203 0.00 0.00 MOLG ATOM 107 C4 BGLA 5 −4.141 −1.042 4.454 0.00 0.00 MOLG ATOM 108 H4 BGLA 5 −3.404 −1.851 4.489 0.00 0.00 MOLG ATOM 109 O4 BGLA 5 −3.822 −0.062 3.386 0.00 0.00 MOLG ATOM 110 C6 BGLA 5 −5.563 −2.274 2.735 0.00 0.00 MOLG ATOM 111 O6A BGLA 5 −6.491 −1.732 1.689 0.00 0.00 MOLG ATOM 112 O6B BGLA 5 −4.656 −3.424 2.409 0.00 0.00 MOLG ATOM 113 C1 ANAG 6 −8.943 −5.604 7.325 0.00 0.00 MOLG ATOM 114 H1 ANAG 6 −9.890 −5.743 7.876 0.00 0.00 MOLG ATOM 115 O1 ANAG 6 −9.245 −5.610 5.933 0.00 0.00 MOLG ATOM 116 HO1 ANAG 6 −9.258 −6.545 5.713 0.00 0.00 MOLG ATOM 117 C5 ANAG 6 −6.734 −6.650 6.952 0.00 0.00 MOLG ATOM 118 H5 ANAG 6 −6.876 −6.578 5.870 0.00 0.00 MOLG ATOM 119 O5 ANAG 6 −8.078 −6.766 7.626 0.00 0.00 MOLG ATOM 120 C2 ANAG 6 −8.247 −4.303 7.828 0.00 0.00 MOLG ATOM 121 H2 ANAG 6 −8.080 −4.392 8.905 0.00 0.00 MOLG ATOM 122 N2 ANAG 6 −9.055 −3.075 7.645 0.00 0.00 MOLG ATOM 123 H2N ANAG 6 −9.292 −2.859 6.686 0.00 0.00 MOLG ATOM 124 C2N ANAG 6 −9.469 −2.259 8.650 0.00 0.00 MOLG ATOM 125 O2N ANAG 6 −9.203 −2.480 9.821 0.00 0.00 MOLG ATOM 126 CME ANAG 6 −10.298 −1.034 8.221 0.00 0.00 MOLG ATOM 127 H1M ANAG 6 −9.788 −0.114 8.530 0.00 0.00 MOLG ATOM 128 H2M ANAG 6 −10.418 −1.031 7.131 0.00 0.00 MOLG ATOM 129 H3M ANAG 6 −11.289 −1.063 8.686 0.00 0.00 MOLG ATOM 130 C3 ANAG 6 −6.886 −4.132 7.117 0.00 0.00 MOLG ATOM 131 H3 ANAG 6 −7.043 −4.055 6.037 0.00 0.00 MOLG ATOM 132 O3 ANAG 6 −6.226 −2.913 7.643 0.00 0.00 MOLG ATOM 133 C4 ANAG 6 −6.025 −5.365 7.455 0.00 0.00 MOLG ATOM 134 H4 ANAG 6 −5.858 −5.422 8.534 0.00 0.00 MOLG ATOM 135 O4 ANAG 6 −4.743 −5.234 6.793 0.00 0.00 MOLG ATOM 136 HO4 ANAG 6 −4.413 −4.328 6.912 0.00 0.00 MOLG ATOM 137 C6 ANAG 6 −5.900 −7.917 7.239 0.00 0.00 MOLG ATOM 138 H61 ANAG 6 −6.412 −8.806 6.866 0.00 0.00 MOLG ATOM 139 H62 ANAG 6 −4.930 −7.851 6.742 0.00 0.00 MOLG ATOM 140 O6 ANAG 6 −5.695 −8.084 8.659 0.00 0.00 MOLG ATOM 141 HO6 ANAG 6 −5.162 −8.869 8.806 0.00 0.00 MOLG END

EXAMPLE 2 Lisinopril

Lisinopril is a hydrophilic organic drug molecule (see FIG. 21) used to treat hypertension, congestive heart failure, heart attacks and is also used to prevent renal and retinal complications of diabetes. Lisinopril is an inhibitor of angiotensin converting enzyme (ACE), which catalyses the conversion of AngiotensinI to AngiotensinII (a potent vasoconstrictor) and is involved in the inactivation of bradykinin (a potent vasodilator). Historically, lisinopril was the third ACE inhibitor developed (after captopril and enalapril) and was introduced into therapy in the early 1990s. Lisinopril was developed by Merck & Co. and is marketed worldwide as Prinivil® and by AstraZeneca as Zestril®. In Australia it is marketed by AlphaPharm as Lisodur®. In this worked example, we demonstrate how the dynamic 3D-solution structure of lisinopril was determined from experimental NMR data using the methodology described in this application.

Chemical Shift Assignment and Measurement of Homonuclear Scalar-Coupling Constants

Lisinopril is a peptidomimetic molecule, having a similar chemical structure to the tripeptide NH₃-Phe-Lys-Pro-COO. The atoms and residues in lisinopril were therefore given names based on nomenclature for this peptide (see Appendix B); the extra saturated carbon in the phenylalanine sidechain is designated CG. Since all NMR data on lisinopril was recorded at pH 6.0, the ionization state of the amine groups (i.e., the backbone secondary amine and the Lys3 sidechain primary amine) and carboxylate groups (in residues Phe1 and Pro3) can be immediately defined from the typical pK_(a) values of these groups as shown in FIG. 21. Partial conjugation of the lone pair of electrons from the proline residue's nitrogen atom with the adjacent carbonyl double-bond results in the presence of both cis and trans stereoisomers of lisinopril in solution (FIG. 22).

The ¹H and ¹³C chemical shifts of both stereoisomers of lisinopril at 278 K were assigned using [¹H-¹H]-COSY, [¹H-¹H]-TOCSY and natural-abundance [¹H-¹³C]-HSQC spectra recorded at 600 MHz on a 20 mM NMR sample (100% D₂O, pH*6.0, 0.3 mM DSS) of lisinopril. By integration of peak volumes for resonances that were distinct for the cis and trans forms, the mole abundance ratio was determined to be 80% trans:20% cis. Since trans-lisinopril was more abundant in the mixture, it was decided at this stage to determine the dynamic 3D-structure of trans lisinopril. The proton chemical shifts for trans lisinopril are given in FIG. 23.

With the exception of the HA protons in trans lisinopril, most protons had complex spectral lineshapes due the large number of scalar-couplings present (as many as five ²J_(HH)/³J_(HH) scalar coupling in the lysine sidechain) and strong-coupling. This complexity prevented the measurement of many scalar-couplings. However, the six ³J_(HH) coupling constants shown in FIG. 23 were measured.

Analysis of Spectral Lineshapes

A 2D [¹H, ¹H]-T-ROESY dataset was used to provide structural restraints for trans lisinopril. This dataset was recorded with sufficient data points in the acquisition dimension to resolve proton multiplet splittings but few enough data points in the indirect dimension to prevent these splittings being resolved (i.e., simplying the analysis of proton multiplets to just the acquisition dimension). The value of λ (1.8 Hz) for this dataset was determined by measurement resonances from ROEs to the Pro3 HA proton. The scaling factor sets for each proton in trans lisinopril in this 2D [¹H, ¹H]-T-ROESY dataset were determined as follows:

Pro3, HA proton: This proton has two ³J_(HH) coupling constants of 6.0 and 8.0 Hz (see FIG. 24), and manifests in the spectrum as a simple doublet of doublets (i.e., as in FIG. 9, two scalar couplings). It therefore has an initial scaling factor set of ƒ_(i)={4, 4, 4, 4}. Each scaling factor is multipled by the mole abundance scaling ratio (=1/0.8) of 1.25 to give the corrected scaling factor set of ƒ_(i)={5, 5, 5, 5}.

Phe 1, HA proton: This proton would be expected to manifest in the spectrum as an ideal triplet (i.e. as shown in FIG. 10, two scalar couplings). However, chemical exchange at the secondary amine group adjacent to this proton results in a further broadening of this proton's multiplet resonances, making this multiplet appear as a broad singlet (i.e., most like FIG. 9, no scalar couplings). The scaling factor set for this proton was therefore estimated by comparing it with that of the Pro3 HA diagonal peak in the spectrum. Using the scaling factor set for Pro3 HA, i.e., f={5, 5, 5, 5}, the true peak-height for the Pro3 HA diagonal peak was determined. Since the Phe1 HA protons would be expected to give a similar true peak-height as the Pro3 HA diagonal in this spectrum, the scaling factor could be estimated as the value required to scale the observed singlet Phe1 HA diagonal peak height to the same value as the true peak height for the Pro3 HA diagonal peak. This gave an estimated scaling factor set of ƒ_(i)={4.5}.

Lys2, HA proton: This proton experienced a similar broadening to that observed for the Phe1 HA proton. It was treated in the same manner, giving an estimated scaling factor set of ƒ_(i)={4.1}.

All other protons: Had very complex lineshapes and suffered from strong-coupling. Their initial scaling-factor sets were determined using the rules for strongly-coupled protons (see above). Each scaling factor was then multiplied by the mole abundance ratio. In summary, the scaling factor sets for proton resonance multiplets in the 2D [¹H, ¹H]-NOESY dataset were as follows:

Phe1 HA {4.5} HB1 {31.8, 17.8, 7.8, 5.6, 5.1, 7.8, 17.1, 40.0} HB2 {31.8, 17.8, 7.8, 5.6, 5.1, 7.8, 17.1, 40.0} HG1 {30.1, 22.1, 12.6, 9.1, 7.4, 8.3, 8.5, 11.4, 23.4, 36.5} HG2 {30.1, 22.1, 12.6, 9.1, 7.4, 8.3, 8.5, 11.4, 23.4, 36.5} HZ1 {2.1, 3.0} HZ2 {2.1, 3.0} HH {6.4, 2.6, 3.9} Lys2 HA {4.1} HB1 {6.6, 4.0, 4.0, 6.6} HB2 {6.6, 4.0, 4.0, 6.6} HG1 {41.6, 17.5, 13.6, 7.6, 5.8, 6.0, 10.4, 24.3, 42.8, 90.4} HG2 {41.6, 17.5, 13.6, 7.6, 5.8, 6.0, 10.4, 24.3, 42.8, 90.4} HD1 {13.4, 5.4, 3.9, 5.0, 12.6} HD2 {13.4, 5.4, 3.9, 5.0, 12.6} HE1 {5.0, 2.5, 5.0} HE2 {5.0, 2.5, 5.0} Pro3 HA {5, 5, 5, 5} HB1 {26.5, 7.0, 4.8, 5.6, 67.5, 12.4} HB2 {5.6, 5.6, 5.6, 7.5} HG1 {22.4, 15.0, 11.0, 9.8, 10.9, 11.4, 10.3, 11.3, 12.9, 19.6} HG2 {22.4, 15.0, 11.0, 9.8, 10.9, 11.4, 10.3, 11.3, 12.9, 19.6} HD1 {16.1, 9.8, 7.3, 5.3, 7.9, 8.1, 17.0} HD2 {16.1, 9.8, 7.3, 5.3, 7.9, 8.1, 17.0}

Measurement and Quantitation of NMR Spectra

Two different kinds of NMR data in seven different experimental NMR datasets were used in the determination of the dynamic solution structure of trans lisinopril:

-   -   1) T-ROESY relaxation data: one experimental dataset, 2D         [¹H-¹H]-T-ROESY     -   2) Conformation-dependent scalar couplings: one experimental         dataset

The pertinent acquisition parameters for each of these different NMR datasets (and the number of structural restraints measured from them) were as follows. The 2D [¹H, ¹H]-T-ROESY spectrum was recorded on a sample of 20 mM lisinopril (100% D₂O, pH*6.0, 0.3 mM DSS) at 600 MHz and 278 K with an ROE mixing time of 400 ms and sweep widths of 7200 Hz in both dimensions. Using the scaling-factor sets described above, 67 ROE structural restraints were measured from this spectrum. Errors on each ROE restraint were determined as described above, using the initial m value of 0.5 for a 2D [¹H, ¹H]-T-ROESY spectrum (39 noROE structural restraints were also inferred from their absence in this spectrum). These ROE and noROE structural restraints are detailed in the dataset file given in Appendix B.

Since the proline ring is in an equilibrium between two known conformations, the two scalar coupling constants to the HA proton in this ring (see FIG. 24) do not help to define the ring's geometry any more precisely; these scalar coupling constants were therefore not used as structural restraints. The remaining four scalar coupling-constants shown in FIG. 24 could be used as structural restraints in structure calculations to help define unknown bond geometries. The best Karplus equation for relating these coupling-constants to the dihedral angle in the molecule is that typically used for χ¹ sidechain geometries in proteins and peptides [39]. The combined error in measurement of the coupling (˜0.3 Hz) and predictive accuracy of these Karplus relations (˜0.3 Hz) is ˜0.5 Hz. The four scalar coupling-constant measurements are listed in the relevant dataset file (see Appendix B).

Molecule Specification

The experimental datasets described above were both acquired in D₂O. In D₂O, all the amine protons in lisinopril exchange very rapidly with solvent deuterons. These protons were therefore defined as NMR-inactive (exc 1 HN*, exc 2 HZ*). All other protons were defined as active (add*H*). The file used to specify this solvent mask was as follows:

remark Solvent mask for lisinopril conditions: solvents 1 endsection solvent: name d2o add * H* exc 1 HN* exc 2 HZ* endsection

The locations of the two oxygen atoms in each carboxylate group in lisinopril relative to the rest of the molecular structure could not be specified from the experimental data. These atoms were therefore set to be van der Waals inactive, as detailed in the following van der Waals input file:

remark Van der Waals mask for lisinopril configuration: vdw.cutoff 6.0 vdw.coupling 1e−4 endsection nonbonded: vdw * H* 0.016 0.60 vdw * C* 0.100 1.91 vdw * N* 0.170 1.82 vdw * O* 0.210 1.66 remark exclude the oxygen atoms in the carboxylate groups exc 1 O* exc 3 O* endsection

Experimental Data Input

The value of τ_(c) has not been precisely measured experimentally for trans lisinopril. However, a 2D-[¹H, ¹H]-NOESY spectrum recorded on the sample of 20 mM HA₆ (100% D₂O, pH 6.0, 0.3 mM DSS) at 600 MHz and 278 K (i.e., identical sample conditions to that used for the 2D [¹H, ¹H]-T-ROESY) showed weak positive NOEs. The formula for the threshold value of τ_(c) at which NOEs become positive (see above) therefore indicates that under these conditions, trans lisinopril has a τ_(c) value less than 0.3 ns; the value was therefore initially set to 0.1 ns. After a few rounds of structure calculations (see above methodology), τ_(c) was found to prefer a value of 0.2 ns; the adjusted solvent viscosity of 100% D₂O at 278 K for the 2D [¹H, ¹H]-T-ROESY dataset was determined to be 1.94, using equations (22) and (23). The two experimental dataset files used in the structure calculations are given in Appendix B.

Dynamic Model

The pertinent conformationally-flexible bonds and chemistries within lisinopril were identified, using the methodology described above (see FIG. 25):

-   -   1) Four single bonds comprising the backbone of the molecule,         namely, N^(F1)-CA^(F1), N^(F1)-CA^(K2), CA^(K2)-C^(K2),         C^(K2)-N^(P3).     -   2) Proline rings adopt two major conformations in solution,         termed N and S states (also termed UP and DOWN conformations, or         C3′-endo and C3′-exo conformations) [15]. In the case of a trans         proline ring, these are found in an ˜50:50 ratio [40].     -   3) The carboxylate group in residue Phe1 can rotate about the         CA^(F1)-C^(F1) single bond. Similarly, the carboxylate group in         residue Pro3 can rotate about the CA^(P3)-C^(P3) single bond.     -   4) The five single bonds in the lysine sidechain can rotate         (CA^(K2)-CB^(K2), CB^(K2)-CG^(K2), CG^(K2)-CD^(K2),         CD^(K2)-CE^(K2), CE^(K2)-NZ^(K2)).     -   5) The three single bonds in the phenylalanine sidechain can         rotate (CA^(F1)-CB^(F1), CB^(F1)-CG^(F1), CG^(F1)-CD^(F1)).

To create a realistic dynamic model of the molecule that could be used to optimise against the observed experimental data, the following degrees of freedom were modelled in the dynamic model file (see below):

-   -   1) The N^(F1)-CA^(F1) and N^(F1)-CA^(K2) bonds are between         sp³-hybridised atoms and therefore require a trimodal model. The         three rotamer states (gt, tg, gg) were specified with variables         1, 2 and 3 (which remain fixed throughout the iterative         optimisation) and each bond was given its own Gaussian spread         value (var 4 and var 5, respectively), which was allowed to vary         throughout the optimisation. The relative populations of the         three rotamer states for each bond were allowed to vary         throughout the optimisation, with probabilities mode 1 and mode         2, respectively. The CA^(K2)-C^(K2) bond is between an         sp³-hybridised atom (CA^(K2)) and an sp² hybridised atom         (C^(K2)) and therefore requires a bimodal model. This was         modelled with two mean values (var 8 and 10) that were allowed         to vary throughout the optimisation, and two different Gaussian         spread values (var 9 and 11). The relative proportion of these         two conformations was allowed to vary with probability mode 3.         Since only the trans form of lisinopril is being modelled, the         C^(K2)-N^(P3) bond is represented with a fixed unimodal model,         taking the mean dihedral angle appropriate for a trans geometry,         i.e. 180°. The Gaussian spread on this bond was set to a small         value and given a small jump size, reflecting the fact that         peptide bonds are fairly rigid.     -   2) The two major conformations of the proline ring have         well-defined geometries [15]. Each bond in the ring was         therefore given a bimodal model of two fixed mean values and a         Gaussian spread of zero. The ring was alternated between the two         states using probability mode 6, which was set to a fixed value         of 0.5, reflecting the 50:50 ratio of these conformations seen         in solution.     -   3) There are no structural restraints involving the carboxylate         oxygen atoms of either carboxylate group and therefore precise         dihedral angle values for bonds CA^(F1)-C^(F1) and         CA^(P3)-C^(P3) cannot be determined from these datasets. To         prevent their initial arbitrary positions influencing the         iterative optimisation, the carboxylate atoms were set to be van         der Waals inactive (see above).     -   4) The CA^(K2)-CB^(K2), CB^(K2)-CG^(K2), CG^(K2)-CD^(K2),         CD^(K2)-CE^(K2), CE^(K2)-NZ^(K2) bonds are all between         sp³-hybridised atoms and therefore require a trimodal model.         Since the HB1 and HB2 protons have the same chemical shift (see         FIG. 23), they require a symmetric trimodal model (var 1, var 2,         var 3, var 7, mode 5 4), i.e., where the probability values for         tg and gt rotamers are always equal and the single remaining         degree of probability freedom is allowed to vary. By the same         reasoning, the CB^(K2)-CG^(K2), CG^(K2)-CD^(K2) and         CD^(K2)-CE^(K2) bonds were also given a symmetric trimodal model         (modes 9, 10 and 11) with probability values that were allowed         to vary and each had their own Gaussian spread (var 29-31). The         CE^(K2)-NZ^(K2) bond was modelled in the same manner as a methyl         group (see for hyaluronan hexassaccharide in Appendix A).     -   5) The CA^(F1)-CB^(F1) and CB^(F1)-CG^(F1) bonds are between         sp³-hybridised atoms and therefore require a trimodal model.         Since the HB protons have the same chemical shifts (see FIG.         23), a symmetric trimodal model was used for the CA^(F1)-CB^(F1)         bond (var 1, var 2, var 3, var 6, mode 4 4) in which the         probability value was allowed to vary. Similarly, since the HG         protons have the same chemical shifts (see FIG. 23), a symmetric         trimodal model was used for the CB^(F1)-CG^(F1) bond (var 1, var         2, var 3, var 6, mode 7 4) in which the probability value was         allowed to vary. The CG^(F1)-CD^(F1) bond is between an         sp³-hybridised atom (CG^(F1)) and an sp²-hybridised atom         (CD^(F1)) and therefore requires a bimodal model. The two         dihedral angle conformations shown in the dynamic model file         (var 26, var 27) were chosen since they model both forms of the         symmetric conformation predominantly observed for this bond in a         wide range of small molecule crystal structures. A single         Gaussian value was given to the bond due to this symmetry (var         28).

The specific implementation of these considerations was achieved using the dynamic model file given below. The relationship of each variable and probability mode to the chemical structure is given in FIG. 26.

remark Dynamic model of lisinopril variables: remark generic trimodal staggered conformation mean angles var 1 fix 60 jump 0.0 start 0.02 # mean 1 var 2 fix 300 jump 0.0 start 0.02 # mean 2 var 3 fix 180 jump 0.0 start 0.02 # mean 3 remark backbone Gaussian spreads var 4 fix 20 jump 5.0 start 0.02 # remark F1CA-K2N bond var 5 fix 20 jump 5.0 start 0.02 # remark K2N-K2CA bond var 6 fix 20 jump 5.0 start 0.02 # remark F1CA-F1CB bond var 7 fix 20 jump 5.0 start 0.02 # remark K2CA-K2CB bond remark K2CA-K2CO bond bimodal model var 8 fix 300 jump 20.0 start 0.02 # remark mean 1 var 9 fix 20 jump 5.0 start 0.02 # remark Gaussian spread 1 var 10 fix 120 jump 20.0 start 0.02 # remark mean 2 var 11 fix 20 jump 5.0 start 0.02 # remark Gaussian spread 2 remark proline amide bond set to trans conformation var 12 fix 180 jump 0.0 start 0.02 # remark mean set to trans var 13 fix 4 jump 2.0 start 0.02 # remark Gaussian spread remark proline ring bimodal flip between N and S states remark parameters for N state = gamma exo = UP var 14 fix −48.82 jump 0.0 start 0.0 # remark dihedral no. 49 mean 1 var 15 fix −46.58 jump 0.0 start 0.0 # remark dihedral no. 54 mean 1 var 16 fix 58.07 jump 0.0 start 0.0 # remark dihedral no. 57 mean 1 var 17 fix −157.04 jump 0.0 start 0.0 # remark dihedral no. 60 mean 1 var 18 fix −48.96 jump 0.0 start 0.0 # remark dihedral no. 63 mean 1 remark parameters for S state = gamma endo = DOWN var 19 fix −74.71 jump 0.0 start 0.0 # remark dihedral no. 49 mean 2 var 20 fix 45.29 jump 0.0 start 0.0 # remark dihedral no. 54 mean 2 var 21 fix −56.00 jump 0.0 start 0.0 # remark dihedral no. 57 mean 2 var 22 fix 157.82 jump 0.0 start 0.0 # remark dihedral no. 60 mean 2 var 23 fix 46.64 jump 0.0 start 0.0 # remark dihedral no. 63 mean 2 remark proline ring bimodal flip Gaussian spread for both states var 24 fix 0.0 jump 0.0 start 0.0 remark ‘phenylalanine’ sidechain var 25 fix 20 jump 5.0 start 0.02 # remark F1CB-F1CG Gaussian spread remark F1CG-F1CD bimodal model and Gaussian spread var 26 fix 90 jump 0.0 start 0.02 # remark mean 1 var 27 fix 270 jump 0.0 start 0.02 # remark mean 2 var 28 fix 20 jump 5.0 start 0.02 # remark Gaussian remark lysine sidechain Gaussian spreads var 29 fix 20 jump 5.0 start 0.02 # remark CB-CG Gaussian spread var 30 fix 20 jump 5.0 start 0.02 # remark CG-CD Gaussian spread var 31 fix 20 jump 5.0 start 0.02 # remark CD-CE Gaussian spread var 32 fix 20 jump 0.0 start 0.02 # remark CE-CZ Gaussian spread endsection probabilities: mode 1 3 0.33 0.66 0.1 # remark F1 CA-N bond mode 2 3 0.33 0.66 0.1 # remark F1 N-CA K2 bond mode 3 2 0.05 0.1 # remark K2 CA-C bond mode 4 4 0.33 0.66 0.1 # remark F1 CA-CB bond mode 5 4 0.33 0.66 0.1 # remark K2 CA-CB bond mode 6 2 0.5 0.0 # remark proline ring flip mode 7 4 0.33 0.66 0.1 # remark F1 CB-CG bond mode 8 2 0.5 0.0 # remark F1CG-CD bond mode 9 4 0.33 0.66 0.1 # remark K2 CB-CG bond mode 10 4 0.33 0.66 0.1 # remark K2 CG-CD bond mode 11 4 0.33 0.66 0.1 # remark K2 CD-CE bond mode 12 3 0.33 0.66 0.0 # remark K2 CE-CZ bond endsection dynamics: remark backbone multigyrate 1 1 1 4 2 4 3 4 # remark F1 CA-N bond multigyrate 27 2 1 5 2 5 3 5 # remark F1 N-CA K2 bond multigyrate 30 3 8 9 10 11 # remark K2 CA-C bond gyrate 47 12 13 # remark P3 amide bond remark ‘phenylalanine’ sidechain multigyrate 8 4 1 6 2 6 3 6 # remark F1 CA-CB bond multigyrate 11 7 1 25 2 25 3 25 # remark F1 CB-CG bond multigyrate 14 8 26 28 27 28 # remark F1 CG-CD bond remark lysine sidechain multigyrate 32 5 1 7 2 7 3 7 # remark K2 CA-CB bond multigyrate 35 9 1 29 2 29 3 29 # remark K2 CB-CG bond multigyrate 38 10 1 30 2 30 3 30 # remark K2 CG-CD bond multigyrate 46 11 1 31 2 31 3 31 # remark K2 CD-CE bond multigyrate 41 12 1 32 2 32 3 32 # remark K2 CE-CZ bond remark proline ring flip multigyrate 49 6 14 24 19 24 multigyrate 54 6 15 24 20 24 multigyrate 57 6 16 24 21 24 multigyrate 60 6 17 24 22 24 multigyrate 63 6 18 24 23 24 endsection

In this manner, all the flexible parts of the trans lisinopril molecule and their behaviour are defined as required for the computer implementation of the ensemble generation algorithm. In this model, there are 13 unknown Gaussian spreads, 2 unknown mean dihedral angle values and 11 probability values to determine in order to solve the solution structure of trans lisinopril.

Structure Calculations

Each round of structure calculations for trans lisinopril comprised 100 runs; a larger number than that used for α-HA₆ (40) was chosen because of the greater number of degrees of freedom being modelled. Statistics were performed on the lowest 25 χ² _(total) runs. Each individual run had 10,000 iteration steps and the dynamic ensemble was composed of 250 structures; a larger number than that used for α-HA₆ (40) was chosen because of the greater number of bi- and trimodal models used in the dynamic model file. The scalar-coupling dataset file (see Appendix B) had low experimental errors and was used from the first round of structure calculations. The base dataset (37 structural restraints) for the 2D [¹H, ¹H]-T-ROESY dataset was established over the first 8 rounds of structure calculations, after which point the structures loosely converged to preferred (and structurally plausible) values for each unknown parameter. The primary and secondary statistics tables for the top 25 of the 100 runs in this round are shown below (only the first 10 ranked run numbers are given):

Round8 statistics: Ranked run no. Parameter Mean StDev 8 32 51 64 29 16 57 91 38 92 T-ROESY 24.07 3.36 17.55 17.63 21.32 20.78 22.91 21.87 23.35 23.63 23.26 19.92 JCOUP 3.01 1.65 3.57 1.30 1.56 1.73 1.11 1.17 2.22 2.49 3.25 7.86 VDW 1.74 0.75 1.44 3.72 1.14 1.88 1.23 3.38 1.29 1.66 1.50 1.18 TotChi 28.81 3.57 22.56 22.64 24.02 24.38 25.26 26.43 26.86 27.78 28.01 28.96 Variables 1-32: sp3-1 60.00 0.00 60.00 60.00 60.00 60.00 60.00 60.00 60.00 60.00 60.00 60.00 sp3-2 300.00 0.00 300.00 300.00 300.00 300.00 300.00 300.00 300.00 300.00 300.00 300.00 sp3-3 180.00 0.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 F1phi-g 14.40 5.83 20.00 9.57 11.91 12.21 22.64 7.70 12.51 14.81 16.70 10.64 K2phi-g 10.81 6.14 1.18 15.77 7.47 10.04 8.35 2.86 0.95 4.02 13.58 10.05 F1chi-g 23.80 12.33 23.28 34.80 25.69 41.83 20.52 15.93 17.20 6.56 8.87 17.50 K1chi-g 21.74 10.83 35.10 13.19 17.84 3.96 20.72 28.29 28.57 16.06 26.60 41.88 Kpsi1 −36.49 18.89 −40.71 −7.52 −3.73 −10.86 −26.74 −36.26 −62.44 −52.87 −26.05 −29.25 Kpsi1-g 19.92 10.25 12.87 16.80 39.80 26.73 13.66 1.26 14.61 23.77 18.42 36.77 Kpsi2 113.76 9.65 117.51 125.54 112.61 121.31 109.99 122.88 104.11 111.54 117.01 130.96 Kpsi2-g 17.07 8.78 28.04 23.73 23.94 21.49 22.61 20.03 16.81 21.27 16.90 3.50 Ptrans 180.00 0.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 180.00 Ptrans-g 5.14 3.31 3.63 8.83 10.83 2.91 0.36 3.16 1.99 6.85 1.41 5.06 P-ring −48.82 0.00 −48.82 −48.82 −48.82 −48.82 −48.82 −48.82 −48.82 −48.82 −48.82 −48.82 P-ring −46.58 0.00 −46.58 −46.58 −46.58 −46.58 −46.58 −46.58 −46.58 −46.58 −46.58 −46.58 P-ring 58.07 0.00 58.07 58.07 58.07 58.07 58.07 58.07 58.07 58.07 58.07 58.07 P-ring −157.04 0.00 −157.04 −157.04 −157.04 −157.04 −157.04 −157.04 −157.04 −157.04 −157.04 −157.04 P-ring −48.96 0.00 −48.96 −48.96 −48.96 −48.96 −48.96 −48.96 −48.96 −48.96 −48.96 −48.96 P-ring −74.71 0.00 −74.71 −74.71 −74.71 −74.71 −74.71 −74.71 −74.71 −74.71 −74.71 −74.71 P-ring 45.29 0.00 45.29 45.29 45.29 45.29 45.29 45.29 45.29 45.29 45.29 45.29 P-ring −56.00 0.00 −56.00 −56.00 −56.00 −56.00 −56.00 −56.00 −56.00 −56.00 −56.00 −56.00 P-ring 157.82 0.00 157.82 157.82 157.82 157.82 157.82 157.82 157.82 157.82 157.82 157.82 P-ring 46.64 0.00 46.64 46.64 46.64 46.64 46.64 46.64 46.64 46.64 46.64 46.64 P-ring-g 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 F1chi2-g 15.21 5.10 12.50 14.54 14.67 13.74 13.61 18.75 19.90 16.31 1.12 23.36 F1chi3 90.00 0.00 90.00 90.00 90.00 90.00 90.00 90.00 90.00 90.00 90.00 90.00 F1chi3 270.00 0.00 270.00 270.00 270.00 270.00 270.00 270.00 270.00 270.00 270.00 270.00 F1chi3-g 29.88 6.24 39.65 24.31 35.28 29.60 32.05 28.21 38.67 30.91 20.82 31.22 K2chi2-g 21.26 10.23 22.83 40.01 3.68 34.80 17.56 25.36 20.55 23.83 31.25 12.04 K2chi3-g 19.91 8.42 20.93 22.39 6.45 21.23 9.33 13.88 19.35 27.45 22.29 20.91 K2chi4-g 17.22 9.27 12.82 27.17 25.59 12.17 20.26 18.75 24.30 24.30 7.10 10.17 K2chi5-g 20.00 0.00 20.00 20.00 20.00 20.00 20.00 20.00 20.00 20.00 20.00 20.00 Probabilities: Fphi1 0.01 0.01 0.00 0.00 0.02 0.00 0.01 0.00 0.00 0.00 0.01 0.00 Fphi1 0.95 0.02 0.94 0.96 0.97 0.95 0.95 0.95 0.99 0.92 0.93 0.94 Kphi1 0.01 0.01 0.00 0.01 0.00 0.00 0.00 0.01 0.00 0.01 0.01 0.01 Kphi1 0.96 0.05 0.99 0.98 0.99 1.00 0.91 0.96 0.96 0.88 1.00 0.95 Kpsi 0.08 0.07 0.00 0.00 0.01 0.00 0.00 0.13 0.09 0.05 0.03 0.07 Fchi1 0.33 0.05 0.29 0.29 0.38 0.32 0.35 0.34 0.28 0.36 0.30 0.35 Fchi1 0.67 0.11 0.57 0.58 0.76 0.63 0.70 0.68 0.55 0.72 0.61 0.70 Kchi1 0.34 0.02 0.35 0.33 0.34 0.34 0.34 0.31 0.33 0.31 0.31 0.37 Kchi1 0.69 0.05 0.69 0.67 0.67 0.68 0.69 0.63 0.66 0.63 0.63 0.74 Pflip 0.50 0.00 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 Fchi2 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Fchi2 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Fchi3 0.50 0.00 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 Kchi2 0.41 0.04 0.44 0.46 0.40 0.50 0.40 0.47 0.43 0.41 0.47 0.39 Kchi2 0.82 0.09 0.88 0.92 0.80 1.00 0.81 0.93 0.86 0.82 0.94 0.79 Kchi3 0.43 0.05 0.49 0.41 0.45 0.45 0.50 0.48 0.43 0.39 0.45 0.43 Kchi3 0.86 0.10 0.97 0.82 0.89 0.89 0.99 0.95 0.87 0.79 0.90 0.87 Kchi4 0.16 0.15 0.00 0.00 0.00 0.00 0.00 0.39 0.17 0.08 0.18 0.23 Kchi4 0.32 0.31 0.00 0.00 0.00 0.00 0.00 0.79 0.34 0.16 0.36 0.46 Kchi5 0.33 0.00 0.33 0.33 0.33 0.33 0.33 0.33 0.33 0.33 0.33 0.33 Kchi5 0.66 0.00 0.66 0.66 0.66 0.66 0.66 0.66 0.66 0.66 0.66 0.66 Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 42 27.1 0.6 0 0 JCOUP 4 3.0 0.8 0 0 2D-T-ROESY 37 24.1 0.7 0 0

In this case, it can be seen that the Chi/Res values are similar for the two datasets, indicating that the 2D-T-ROESY does not particularly dominate the scalar-coupling dataset (JCOUP), i.e., the m value of 0.4 is suitable.

In the next 29 rounds of structure calculations, more ROE structural restraints and many noROE structure restraints were included. The results from the round of structure calculations, where the 2D [¹H, ¹H]-T-ROESY dataset had been completely analysed, were as follows:

Round37 statistics: Ranked run no. Parameter Mean StDev 41 98 86 29 94 T-ROESY 161.6 3.50 156.19 154.83 154.78 155.06 157.52 . . . JCOUP 3.0 1.04 1.30 2.65 4.63 3.76 2.99 . . . VDW 2.1 0.92 0.33 1.23 0.95 2.94 1.66 . . . TotChi 166.7 4.35 157.82 158.71 160.36 161.76 162.17 . . . Variables 1-32: sp3-1 60.00 0.00 60.00 60.00 60.00 60.00 60.00 . . . sp3-2 300.00 0.00 300.00 300.00 300.00 300.00 300.00 . . . sp3-3 180.00 0.00 180.00 180.00 180.00 180.00 180.00 . . . F1phi-g 14.75 3.32 14.35 12.87 18.03 13.38 16.16 . . . K2phi-g 9.14 4.87 2.31 3.48 11.46 7.23 10.41 . . . F1chi-g 22.56 6.30 20.51 23.87 15.22 18.25 26.70 . . . F1chi-g 18.29 7.96 21.38 18.13 6.21 17.12 20.40 . . . Kpsi1 −40.16 17.70 −39.79 −37.90 −21.28 −1.03 −46.05 . . . Kpsi1-g 17.68 9.12 32.62 8.91 22.82 20.11 26.41 . . . Kpsi2 115.23 5.78 113.36 110.31 107.36 119.39 117.51 . . . Kpsi2-g 20.08 7.20 21.62 2.32 22.33 23.71 30.12 . . . Ptrans 180.00 0.00 180.00 180.00 180.00 180.00 180.00 . . . Ptrans-g 6.03 3.26 6.54 8.73 2.86 4.33 5.93 . . . P-ring −48.82 0.00 −48.82 −48.82 −48.82 −48.82 −48.82 . . . P-ring −46.58 0.00 −46.58 −46.58 −46.58 −46.58 −46.58 . . . P-ring 58.07 0.00 58.07 58.07 58.07 58.07 58.07 . . . P-ring −157.04 0.00 −157.04 −157.04 −157.04 −157.04 −157.04 . . . P-ring −48.96 0.00 −48.96 −48.96 −48.96 −48.96 −48.96 . . . P-ring −74.71 0.00 −74.71 −74.71 −74.71 −74.71 −74.71 . . . P-ring 45.29 0.00 45.29 45.29 45.29 45.29 45.29 . . . P-ring −56.00 0.00 −56.00 −56.00 −56.00 −56.00 −56.00 . . . P-ring 157.82 0.00 157.82 157.82 157.82 157.82 157.82 . . . P-ring 46.64 0.00 46.64 46.64 46.64 46.64 46.64 . . . P-ring-g 0.00 0.00 0.00 0.00 0.00 0.00 0.00 . . . F1chi2-g 12.88 3.45 14.63 13.65 17.19 5.57 9.88 . . . F1chi3 90.00 0.00 90.00 90.00 90.00 90.00 90.00 . . . F1chi3 270.00 0.00 270.00 270.00 270.00 270.00 270.00 . . . F1chi3-g 30.55 5.92 29.41 37.53 30.43 34.58 23.76 . . . K2chi2-g 21.55 5.45 14.20 19.68 24.80 31.48 23.98 . . . K2chi3-g 24.39 7.71 11.39 26.76 22.78 13.10 32.87 . . . K2chi4-g 18.93 6.00 13.19 14.93 23.30 23.13 11.30 . . . K2chi5-g 20.00 0.00 20.00 20.00 20.00 20.00 20.00 . . . Probabilities: Fphi1 0.00 0.00 0.00 0.00 0.01 0.01 0.00 . . . Fphi1 0.95 0.02 0.97 0.96 0.95 0.94 0.97 . . . Kphi1 0.00 0.01 0.00 0.01 0.00 0.00 0.00 . . . Kphi1 0.96 0.04 0.89 1.00 1.00 0.92 0.88 . . . Kpsi 0.08 0.09 0.04 0.23 0.01 0.02 0.03 . . . Fchi1 0.34 0.02 0.31 0.36 0.33 0.30 0.31 . . . Fchi1 0.68 0.05 0.62 0.72 0.66 0.60 0.63 . . . Kchi1 0.34 0.02 0.36 0.37 0.34 0.36 0.35 . . . Kchi1 0.68 0.04 0.72 0.75 0.67 0.73 0.70 . . . Pflip 0.50 0.00 0.50 0.50 0.50 0.50 0.50 . . . Fchi2 0.00 0.00 0.00 0.00 0.00 0.00 0.00 . . . Fchi2 0.00 0.00 0.00 0.00 0.00 0.00 0.00 . . . Fchi3 0.50 0.00 0.50 0.50 0.50 0.50 0.50 . . . Kchi2 0.41 0.04 0.41 0.37 0.48 0.45 0.41 . . . Kchi2 0.83 0.08 0.82 0.75 0.97 0.91 0.81 . . . Kchi3 0.47 0.03 0.48 0.45 0.41 0.49 0.48 . . . Kchi3 0.93 0.07 0.96 0.91 0.81 0.97 0.95 . . . Kchi4 0.12 0.12 0.13 0.00 0.16 0.00 0.34 . . . Kchi4 0.25 0.25 0.27 0.00 0.33 0.00 0.68 . . . Kchi5 0.33 0.00 0.33 0.33 0.33 0.33 0.33 . . . Kchi5 0.66 0.00 0.66 0.66 0.66 0.66 0.66 . . . Dataset Restraints Tot Chi Chi/Res Viol (>10) Percent TOTAL 110 164.6 1.5 0 0 JCOUP 4 3.0 0.8 0 0 2D-T-ROESY 67 122.5 1.8 0 0 2D-ROE (no) 39 39.1 1.0 0 0

As can be seen from these results, the values for each of the parameters, in particular the backbone bonds' mean values, Gaussian spreads and probability values, are similar to the results from round8. No structural restraint has an χ² _(restraint) value greater than 10.0. Since the inclusion of the additional data (68 structural restraints) relative to round8 did not alter appreciably alter the optimised dynamic structure, the dynamic structure has been solved to a first approximation. By inclusion of other kinds of NMR datasets a more complete view of the dynamic structure of this molecule would easily be obtained (as described above for the hyaluronan hexasaccharide).

The coordinates for the mean dynamic solution structure for trans lisinopril, generated according to these values, is given in Appendix B. Several visual representations of the mean dynamic structure and dynamic ensemble of structures are given in FIGS. 27-29.

APPENDIX B Lisinopril

Starting PDB 3D-Coordinates for Lisinopril

ATOM 1 N PHE 1 41.892 33.386 47.518 1.00 14.83 N ATOM 2 C PHE 1 42.413 35.599 48.383 1.00 13.57 C ATOM 3 CA PHE 1 41.287 34.591 48.121 1.00 14.83 C ATOM 4 CB PHE 1 40.573 34.333 49.466 1.00 12.04 C ATOM 5 CG PHE 1 39.958 35.712 49.908 1.00 13.87 C ATOM 6 CD PHE 1 39.145 35.742 51.173 1.00 15.99 C ATOM 7 CE1 PHE 1 38.817 36.998 51.671 1.00 16.62 C ATOM 8 CZ1 PHE 1 38.060 37.122 52.827 1.00 18.46 C ATOM 9 CZ2 PHE 1 37.952 34.724 52.998 1.00 17.75 C ATOM 10 CE2 PHE 1 38.710 34.598 51.839 1.00 14.59 C ATOM 11 CH PHE 1 37.626 35.983 53.493 1.00 18.68 C ATOM 12 O1 PHE 1 43.578 35.177 48.743 1.00 15.16 O ATOM 13 O2 PHE 1 42.213 36.867 48.241 1.00 13.89 O ATOM 14 HN1 PHE 1 42.639 33.070 48.151 1.00 15.26 H ATOM 15 HN2 PHE 1 41.187 32.646 47.426 1.00 15.26 H ATOM 16 HA PHE 1 40.522 35.003 47.465 1.00 15.26 H ATOM 17 HB1 PHE 1 39.765 33.604 49.315 1.00 15.26 H ATOM 18 HB2 PHE 1 41.280 33.954 50.217 1.00 15.26 H ATOM 19 HG1 PHE 1 40.729 36.481 50.019 1.00 15.26 H ATOM 20 HG2 PHE 1 39.298 36.063 49.103 1.00 15.26 H ATOM 21 HE1 PHE 1 39.147 37.868 51.160 1.00 15.26 H ATOM 22 HE2 PHE 1 38.945 33.635 51.475 1.00 15.26 H ATOM 23 HZ1 PHE 1 37.813 38.085 53.200 1.00 15.26 H ATOM 24 HZ2 PHE 1 37.618 33.858 53.507 1.00 15.26 H ATOM 25 HH PHE 1 37.047 36.074 54.375 1.00 15.26 H ATOM 26 NZ LYS 2 43.457 27.603 44.528 1.00 21.85 N ATOM 27 C LYS 2 41.351 34.015 45.039 1.00 13.99 C ATOM 28 CA LYS 2 42.481 33.694 46.117 1.00 12.80 C ATOM 29 CB LYS 2 43.308 32.421 45.667 1.00 14.69 C ATOM 30 CG LYS 2 42.490 31.102 45.569 1.00 16.12 C ATOM 31 CD LYS 2 43.411 29.976 45.107 1.00 17.50 C ATOM 32 CE LYS 2 42.590 28.689 44.990 1.00 20.10 C ATOM 33 O LYS 2 40.868 33.083 44.393 1.00 13.04 O ATOM 34 HA LYS 2 43.163 34.547 46.194 1.00 15.26 H ATOM 35 HB1 LYS 2 43.752 32.630 44.684 1.00 15.26 H ATOM 36 HB2 LYS 2 44.111 32.257 46.399 1.00 15.26 H ATOM 37 HG1 LYS 2 42.063 30.855 46.551 1.00 15.26 H ATOM 38 HG2 LYS 2 41.687 31.208 44.841 1.00 15.26 H ATOM 39 HD1 LYS 2 43.833 30.230 44.124 1.00 15.26 H ATOM 40 HD2 LYS 2 44.224 29.837 45.831 1.00 15.26 H ATOM 41 HE1 LYS 2 41.777 28.841 44.265 1.00 15.26 H ATOM 42 HE2 LYS 2 42.165 28.434 45.970 1.00 15.26 H ATOM 43 HZ1 LYS 2 42.907 26.737 44.446 1.00 15.26 H ATOM 44 HZ2 LYS 2 44.221 27.464 45.203 1.00 15.26 H ATOM 45 HZ3 LYS 2 43.850 27.849 43.609 1.00 15.26 H ATOM 46 N PRO 3 40.930 35.339 44.618 1.00 13.77 N ATOM 47 C PRO 3 40.142 34.777 42.294 1.00 13.82 C ATOM 48 CA PRO 3 39.936 35.545 43.566 1.00 14.91 C ATOM 49 CB PRO 3 40.139 37.060 43.316 1.00 14.97 C ATOM 50 CG PRO 3 40.147 37.501 44.731 1.00 16.22 C ATOM 51 CD PRO 3 41.336 36.609 45.160 1.00 12.52 C ATOM 52 O1 PRO 3 39.211 34.122 41.809 1.00 13.99 O ATOM 53 O2 PRO 3 41.287 34.807 41.704 1.00 11.94 O ATOM 54 HA PRO 3 38.938 35.354 43.983 1.00 15.26 H ATOM 55 HB1 PRO 3 41.132 37.258 42.891 1.00 15.26 H ATOM 56 HB2 PRO 3 39.356 37.495 42.680 1.00 15.26 H ATOM 57 HG1 PRO 3 40.335 38.572 44.882 1.00 15.26 H ATOM 58 HG2 PRO 3 39.211 37.191 45.222 1.00 15.26 H ATOM 59 HD1 PRO 3 41.502 36.613 46.212 1.00 15.26 H ATOM 60 HD2 PRO 3 42.247 36.931 44.638 1.00 15.26 H END

Internal Coordinate Table for Lisinopril

1 2 CA 1 N 1 CA 1 C 1.55099 111.214 −49.413 107.805 1.53412 2 2 CA 1 CA 1 *N 1 HN1 1.55099 111.214 120.217 107.302 1.02879 3 2 CA 1 CA 1 *N 1 HN2 1.55099 111.214 −120.767 110.12 1.02612 4 1 C 1 N 1 *CA 1 CB 1.53412 107.805 −119.227 114.091 1.54493 5 1 C 1 N 1 *CA 1 HA 1.53412 107.805 122.427 110.539 1.08884 6 1 O1 1 C 1 CA 1 N 1.29014 119.706 −35.4021 107.805 1.47667 7 1 O1 1 CA 1 *C 1 O2 1.29014 119.706 179.56 120.836 1.29128 8 1 N 1 CA 1 CB 1 CG 1.47667 114.091 71.909 106.213 1.57305 9 1 CG 1 CA 1 *CB 1 HB1 1.57305 106.213 118.006 109.355 1.09863 10 1 CG 1 CA 1 *CB 1 HB2 1.57305 106.213 −120.897 110.782 1.09899 11 1 CA 1 CB 1 CG 1 CD 1.54493 106.213 150.504 117.7 1.50383 12 1 CD 1 CB 1 *CG 1 HG1 1.50383 117.7 123.412 111.66 1.09469 13 1 CD 1 CB 1 *CG 1 HG2 1.50383 117.7 −120.624 107.976 1.09833 14 1 CB 1 CG 1 CD 1 CE1 1.57305 117.7 137.931 116.563 1.3902 15 1 CE1 1 CG 1 *CD 1 CE2 1.3902 116.563 179.409 123.672 1.39382 16 1 CG 1 CD 1 CE1 1 CZ1 1.50383 116.563 179.433 120.574 1.38722 17 1 CZ1 1 CD 1 *CE1 1 HE1 1.38722 120.574 −179.819 119.613 1.06262 18 1 CD 1 CE1 1 CZ1 1 CH 1.3902 120.574 0.0518447 119.748 1.38847 19 1 CH 1 CE1 1 *CZ1 1 HZ1 1.38847 119.748 179.964 120.06 1.06167 20 1 CG 1 CD 1 CE2 1 CZ2 1.50383 123.672 −179.446 119.613 1.39098 21 1 CZ2 1 CD 1 *CE2 1 HE2 1.39098 119.613 179.811 120.943 1.05583 22 1 CH 1 CZ2 1 CE2 1 CD 1.39169 120.368 0.060035 119.613 1.39382 23 1 CH 1 CE2 1 *CZ2 1 HZ2 1.39169 120.368 179.872 119.904 1.05835 24 1 CE1 1 CZ1 1 CH 1 CZ2 1.38722 119.748 −0.0465081 119.934 1.39169 25 1 CZ2 1 CZ1 1 *CH 1 HH 1.39169 119.934 −179.91 119.974 1.05939 26 1 CE2 1 CZ2 1 CH 1 CZ1 1.39098 120.368 −0.00939496 119.934 1.38847 27 1 CA 1 N 2 CA 2 C 1.47667 111.214 −58.9079 112.423 1.59418 28 2 C 1 N 2 *CA 2 CB 1.59418 112.423 −120.806 107.173 1.58435 29 2 C 1 N 2 *CA 2 HA 1.59418 112.423 121.63 109.154 1.0942 30 3 N 2 C 2 CA 1 N 1.45189 125.802 115.244 112.423 1.55099 31 3 N 2 CA 2 *C 2 O 1.45189 125.802 172.215 118.71 1.23239 32 1 N 2 CA 2 CB 2 CG 1.55099 107.173 58.1242 115.134 1.55469 33 2 CG 2 CA 2 *CB 2 HB1 1.55469 115.134 121.594 108.176 1.09909 34 2 CG 2 CA 2 *CB 2 HB2 1.55469 115.134 −120.232 108.175 1.09877 35 2 CA 2 CB 2 CG 2 CD 1.58435 115.134 38.7557 109.135 1.52637 36 2 CD 2 CB 2 *CG 2 HG1 1.52637 109.135 120.428 109.785 1.09942 37 2 CD 2 CB 2 *CG 2 HG2 1.52637 109.135 −118.93 110.322 1.08936 38 2 CB 2 CG 2 CD 2 CE 1.55469 109.135 −172.096 108.605 1.53124 39 2 CE 2 CG 2 *CD 2 HD1 1.53124 108.605 119.326 109.365 1.09947 40 2 CE 2 CG 2 *CD 2 HD2 1.53124 108.605 −120.336 109.916 1.09738 41 2 HZ1 2 NZ 2 CE 2 CD 1.02865 109.459 63.4589 109.228 1.53124 42 2 HZ1 2 CE 2 *NZ 2 HZ2 1.02865 109.459 −120.167 109.431 1.02873 43 2 HZ1 2 CE 2 *NZ 2 HZ3 1.02865 109.459 119.886 109.27 1.03014 44 2 CD 2 NZ 2 *CE 2 HE1 1.53124 109.228 119.698 109.437 1.09938 45 2 CD 2 NZ 2 *CE 2 HE2 1.53124 109.228 −120.062 109.777 1.0988 46 2 CG 2 CD 2 CE 2 NZ 1.52637 108.605 104.867 109.228 1.46455 47 2 CA 2 C 3 N 3 CA 1.59418 125.802 −165.648 122.302 1.46212 48 3 CA 2 C 3 *N 3 CD 1.46212 122.302 177.147 127.858 1.43897 49 2 C 3 N 3 CA 3 C 1.45189 122.302 −48.7512 116.415 1.50051 50 3 C 3 N 3 *CA 3 CB 1.50051 116.415 −118.387 99.5022 1.54892 51 3 C 3 N 3 *CA 3 HA 1.50051 116.415 126.034 108.65 1.09811 52 3 O1 3 C 3 CA 3 N 1.23681 120.011 129.838 116.415 1.46212 53 3 O1 3 CA 3 *C 3 O2 1.23681 120.011 179.538 119.877 1.28844 54 3 N 3 CA 3 CB 3 CG 1.46212 99.5022 −46.5389 97.8978 1.48153 55 3 CG 3 CA 3 *CB 3 HB1 1.48153 97.8978 112.881 110.888 1.09815 56 3 CG 3 CA 3 *CB 3 HB2 1.48153 97.8978 −122.661 112.769 1.09818 57 3 CA 3 CB 3 CG 3 CD 1.54892 97.8978 58.0691 95.6158 1.54739 58 3 CD 3 CB 3 *CG 3 HG1 1.54739 95.6158 118.701 114.975 1.09786 59 3 CD 3 CB 3 *CG 3 HG2 1.54739 95.6158 −115.301 109.706 1.10133 60 2 C 3 N 3 CD 3 CG 1.45189 127.858 −157.073 100.77 1.54739 61 3 CG 3 N 3 *CD 3 HD1 1.54739 100.77 121.749 114.771 1.06576 62 3 CG 3 N 3 *CD 3 HD2 1.54739 100.77 −115.09 108.34 1.09734 63 3 CB 3 CG 3 CD 3 N 1.48153 95.6158 −49.0119 100.77 1.43897

[¹H-¹H]-T-ROESY Dataset for Lisinopril

remark 2D-T-ROESY data for TRANS lisinopril configuration: field 600 solvent d2o temp 278 visc  1.94 ident 2D-T-ROESY mix_time 400 ms endsection data: remark ROE no. ring ring donor ring ring acc int error code asgn 1 F 1 HA K 2 HD1 −2.01 0.88 0 ovlp 1 F 1 HA K 2 HD2 −2.01 0.88 0 asgn 2 F 1 HG1 K 2 HD1 −2.37 1.44 0 ovlp 2 F 1 HG2 K 2 HD1 −2.37 1.44 0 ovlp 2 F 1 HG2 K 2 HD2 −2.37 1.44 0 ovlp 2 F 1 HG1 K 2 HD2 −2.37 1.44 0 asgn 3 K 2 HD1 P 3 HA −1.42 0.79 0 ovlp 3 K 2 HD2 P 3 HA −1.42 0.79 0 asgn 4 F 1 HE1 F 1 HA −12.13 6.06 0 ovlp 4 F 1 HZ2 F 1 HA −12.13 6.06 0 ovlp 4 F 1 HE2 F 1 HA −12.13 6.06 0 ovlp 4 F 1 HZ1 F 1 HA −12.13 6.06 0 asgn 5 F 1 HH F 1 HA −1.97 0.99 0 asgn 6 K 2 HA F 1 HA −24.12 12.06 0 asgn 7 K 2 HB1 F 1 HA −5.08 2.54 0 ovlp 7 K 2 HB2 F 1 HA −5.08 2.54 0 asgn 8 K 2 HD1 F 1 HA −2.03 1.01 0 ovlp 8 K 2 HD2 F 1 HA −2.03 1.01 0 asgn 9 P 3 HA F 1 HA −13.05 6.53 0 asgn 10 P 3 HB1 F 1 HA −3.18 1.59 0 asgn 11 P 3 HA F 1 HB1 −2.16 1.08 0 ovlp 11 P 3 HA F 1 HB2 −2.16 1.08 0 asgn 12 F 1 HG1 F 1 HG1 3027.97 1513.98 0 ovlp 12 F 1 HG1 F 1 HG2 3027.97 1513.98 0 ovlp 12 F 1 HG2 F 1 HG1 3027.97 1513.98 0 ovlp 12 F 1 HG2 F 1 HG2 3027.97 1513.98 0 asgn 13 F 1 HE1 F 1 HG1 −164.49 82.25 0 ovlp 13 F 1 HZ2 F 1 HG2 −164.49 82.25 0 ovlp 13 F 1 HE2 F 1 HG1 −164.49 82.25 0 ovlp 13 F 1 HZ1 F 1 HG2 −164.49 82.25 0 ovlp 13 F 1 HE1 F 1 HG2 −164.49 82.25 0 ovlp 13 F 1 HE2 F 1 HG2 −164.49 82.25 0 ovlp 13 F 1 HZ2 F 1 HG1 −164.49 82.25 0 ovlp 13 F 1 HZ1 F 1 HG1 −164.49 82.25 0 asgn 14 F 1 HG1 K 2 HG1 −2.86 0.88 0 ovlp 14 F 1 HG2 K 2 HG1 −2.86 0.88 0 ovlp 14 F 1 HG1 K 2 HG2 −2.86 0.88 0 ovlp 14 F 1 HG2 K 2 HG2 −2.86 0.88 0 asgn 15 K 2 HD1 F 1 HG1 −3.99 2.00 0 ovlp 15 K 2 HD1 F 1 HG2 −3.99 2.00 0 ovlp 15 K 2 HD2 F 1 HG1 −3.99 2.00 0 ovlp 15 K 2 HD2 F 1 HG2 −3.99 2.00 0 asgn 16 P 3 HA F 1 HG1 −4.93 2.47 0 ovlp 16 P 3 HA F 1 HG2 −4.93 2.47 0 asgn 17 P 3 HB2 F 1 HG1 −6.58 3.29 0 ovlp 17 P 3 HB2 F 1 HG2 −6.58 3.29 0 asgn 18 F 1 HE1 F 1 HE1 13344.29 6672.15 0 ovlp 18 F 1 HE2 F 1 HE1 13344.29 6672.15 0 ovlp 18 F 1 HZ2 F 1 HE1 13344.29 6672.15 0 ovlp 18 F 1 HZ1 F 1 HZ2 13344.29 6672.15 0 ovlp 18 F 1 HE2 F 1 HZ1 13344.29 6672.15 0 ovlp 18 F 1 HE2 F 1 HE2 13344.29 6672.15 0 ovlp 18 F 1 HZ2 F 1 HZ2 13344.29 6672.15 0 ovlp 18 F 1 HE2 F 1 HZ2 13344.29 6672.15 0 ovlp 18 F 1 HZ1 F 1 HZ1 13344.29 6672.15 0 ovlp 18 F 1 HE1 F 1 HE2 13344.29 6672.15 0 ovlp 18 F 1 HE1 F 1 HZ2 13344.29 6672.15 0 ovlp 18 F 1 HZ1 F 1 HE1 13344.29 6672.15 0 ovlp 18 F 1 HZ1 F 1 HE2 13344.29 6672.15 0 ovlp 18 F 1 HZ2 F 1 HE2 13344.29 6672.15 0 ovlp 18 F 1 HZ2 F 1 HZ1 13344.29 6672.15 0 ovlp 18 F 1 HE1 F 1 HZ1 13344.29 6672.15 0 asgn 19 F 1 HA F 1 HE1 −10.76 5.38 0 ovlp 19 F 1 HA F 1 HE2 −10.76 5.38 0 ovlp 19 F 1 HA F 1 HZ2 −10.76 5.38 0 ovlp 19 F 1 HA F 1 HZ1 −10.76 5.38 0 asgn 20 F 1 HG1 F 1 HE1 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HE2 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HZ2 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HZ1 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HZ1 −104.88 52.44 0 ovlp 20 F 1 HG1 F 1 HE2 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HE1 −104.88 52.44 0 ovlp 20 F 1 HG2 F 1 HZ2 −104.88 52.44 0 asgn 21 P 3 HA F 1 HE1 −12.55 6.27 0 ovlp 21 P 3 HA F 1 HZ1 −12.55 6.27 0 ovlp 21 P 3 HA F 1 HE2 −12.55 6.27 0 ovlp 21 P 3 HA F 1 HZ2 −12.55 6.27 0 asgn 22 P 3 HD1 F 1 HE1 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HZ1 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HE1 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HZ1 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HE2 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HZ2 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HZ2 −6.16 3.08 0 ovlp 22 P 3 HD2 F 1 HE2 −6.16 3.08 0 asgn 23 F 1 HH F 1 HH 12824.54 6412.27 0 asgn 24 P 3 HA F 1 HH −19.16 9.58 0 asgn 25 K 2 HG1 K 2 HA −6.62 3.31 0 ovlp 25 K 2 HG2 K 2 HA −6.62 3.31 0 asgn 26 F 1 HA K 2 HA −10.36 5.18 0 asgn 27 F 1 HB1 K 2 HA −1.29 0.64 0 ovlp 27 F 1 HB2 K 2 HA −1.29 0.64 0 asgn 28 P 3 HD1 K 2 HA −48.23 24.11 0 ovlp 28 P 3 HD2 K 2 HA −48.23 24.11 0 asgn 29 K 2 HB1 K 2 HB1 980.97 490.49 0 ovlp 29 K 2 HB2 K 2 HB1 980.97 490.49 0 ovlp 29 K 2 HB1 K 2 HB2 980.97 490.49 0 ovlp 29 K 2 HB2 K 2 HB2 980.97 490.49 0 asgn 30 F 1 HA K 2 HB1 −3.12 1.56 0 ovlp 30 F 1 HA K 2 HB2 −3.12 1.56 0 asgn 31 F 1 HE1 K 2 HB1 −0.65 0.32 0 ovlp 31 F 1 HE2 K 2 HB1 −0.65 0.32 0 ovlp 31 F 1 HE1 K 2 HB2 −0.65 0.32 0 ovlp 31 F 1 HE2 K 2 HB2 −0.65 0.32 0 ovlp 31 F 1 HZ1 K 2 HB1 −0.65 0.32 0 ovlp 31 F 1 HZ2 K 2 HB1 −0.65 0.32 0 ovlp 31 F 1 HZ1 K 2 HB2 −0.65 0.32 0 ovlp 31 F 1 HZ2 K 2 HB2 −0.65 0.32 0 asgn 32 P 3 HA K 2 HB1 −24.34 12.17 0 ovlp 32 P 3 HA K 2 HB2 −24.34 12.17 0 asgn 33 P 3 HD1 K 2 HB1 −84.00 42.00 0 ovlp 33 P 3 HD2 K 2 HB1 −84.00 42.00 0 ovlp 33 P 3 HD1 K 2 HB2 −84.00 42.00 0 ovlp 33 P 3 HD2 K 2 HB2 −84.00 42.00 0 asgn 34 K 2 HG1 K 2 HG1 767.20 383.60 0 ovlp 34 K 2 HG1 K 2 HG2 767.20 383.60 0 ovlp 34 K 2 HG2 K 2 HG1 767.20 383.60 0 ovlp 34 K 2 HG2 K 2 HG2 767.20 383.60 0 asgn 35 K 2 HA K 2 HG1 −13.62 6.81 0 ovlp 35 K 2 HA K 2 HG2 −13.62 6.81 0 asgn 36 K 2 HE1 K 2 HG1 −170.41 85.21 0 ovlp 36 K 2 HE2 K 2 HG1 −170.41 85.21 0 ovlp 36 K 2 HE1 K 2 HG2 −170.41 85.21 0 ovlp 36 K 2 HE2 K 2 HG2 −170.41 85.21 0 asgn 37 F 1 HE1 K 2 HG1 −0.49 0.24 0 ovlp 37 F 1 HE1 K 2 HG2 −0.49 0.24 0 ovlp 37 F 1 HZ1 K 2 HG2 −0.49 0.24 0 ovlp 37 F 1 HZ2 K 2 HG1 −0.49 0.24 0 ovlp 37 F 1 HZ1 K 2 HG1 −0.49 0.24 0 ovlp 37 F 1 HE2 K 2 HG1 −0.49 0.24 0 ovlp 37 F 1 HE2 K 2 HG2 −0.49 0.24 0 ovlp 37 F 1 HZ2 K 2 HG2 −0.49 0.24 0 asgn 38 P 3 HA K 2 HG1 −3.66 1.83 0 ovlp 38 P 3 HA K 2 HG2 −3.66 1.83 0 asgn 39 P 3 HD1 K 2 HG1 −27.73 13.86 0 ovlp 39 P 3 HD2 K 2 HG2 −27.73 13.86 0 ovlp 39 P 3 HD2 K 2 HG1 −27.73 13.86 0 ovlp 39 P 3 HD1 K 2 HG2 −27.73 13.86 0 asgn 40 K 2 HD1 K 2 HD1 1112.30 556.15 0 ovlp 40 K 2 HD2 K 2 HD1 1112.30 556.15 0 ovlp 40 K 2 HD2 K 2 HD2 1112.30 556.15 0 ovlp 40 K 2 HD1 K 2 HD2 1112.30 556.15 0 asgn 41 F 1 HE1 K 2 HD1 −0.81 0.40 0 asgn 41 F 1 HE2 K 2 HD1 −0.81 0.40 0 asgn 41 F 1 HZ1 K 2 HD1 −0.81 0.40 0 asgn 41 F 1 HZ2 K 2 HD1 −0.81 0.40 0 asgn 41 F 1 HE1 K 2 HD2 −0.81 0.40 0 asgn 41 F 1 HE2 K 2 HD2 −0.81 0.40 0 asgn 41 F 1 HZ1 K 2 HD2 −0.81 0.40 0 asgn 41 F 1 HZ2 K 2 HD2 −0.81 0.40 0 asgn 42 F 1 HH K 2 HD1 −0.51 0.25 0 ovlp 42 F 1 HE2 K 2 HD2 −0.81 0.40 0 ovlp 42 F 1 HZ1 K 2 HD1 −0.81 0.40 0 ovlp 42 F 1 HH K 2 HD2 −0.51 0.25 0 ovlp 42 F 1 HZ1 K 2 HD1 −0.81 0.40 0 ovlp 42 F 1 HE1 K 2 HD2 −0.81 0.40 0 ovlp 42 F 1 HZ2 K 2 HD2 −0.81 0.40 0 ovlp 42 F 1 HZ2 K 2 HD2 −0.81 0.40 0 ovlp 42 F 1 HE2 K 2 HD1 −0.81 0.40 0 asgn 43 P 3 HA K 2 HD1 −3.00 1.50 0 ovlp 43 P 3 HA K 2 HD2 −3.00 1.50 0 asgn 44 P 3 HD1 K 2 HD1 −21.06 10.53 0 ovlp 44 P 3 HD2 K 2 HD1 −21.06 10.53 0 ovlp 44 P 3 HD1 K 2 HD2 −21.06 10.53 0 ovlp 44 P 3 HD2 K 2 HD2 −21.06 10.53 0 asgn 45 K 2 HE1 K 2 HE1 10977.13 5488.57 0 ovlp 45 K 2 HE2 K 2 HE1 10977.13 5488.57 0 ovlp 45 K 2 HE1 K 2 HE2 10977.13 5488.57 0 ovlp 45 K 2 HE2 K 2 HE2 10977.13 5488.57 0 asgn 46 P 3 HA P 3 HA 4186.68 2093.34 0 asgn 47 P 3 HD1 P 3 HA −16.65 8.33 0 ovlp 47 P 3 HD2 P 3 HA −16.65 8.33 0 asgn 48 F 1 HA P 3 HA −11.50 5.75 0 asgn 49 F 1 HE1 P 3 HA −11.26 5.63 0 ovlp 49 F 1 HE2 P 3 HA −11.26 5.63 0 ovlp 49 F 1 HZ1 P 3 HA −11.26 5.63 0 ovlp 49 F 1 HZ2 P 3 HA −11.26 5.63 0 asgn 50 F 1 HH P 3 HA −6.54 3.27 0 asgn 51 P 3 HB1 P 3 HB1 2659.43 1329.72 0 asgn 52 P 3 HA P 3 HB1 −201.63 100.82 0 asgn 53 P 3 HD1 P 3 HB1 −32.47 16.24 0 ovlp 53 P 3 HD2 P 3 HB1 −32.47 16.24 0 asgn 54 F 1 HE1 P 3 HB1 −4.25 2.13 0 ovlp 54 F 1 HE2 P 3 HB1 −4.25 2.13 0 ovlp 54 F 1 HZ1 P 3 HB1 −4.25 2.13 0 ovlp 54 F 1 HZ2 P 3 HB1 −4.25 2.13 0 asgn 55 F 1 HH P 3 HB1 −3.21 1.60 0 asgn 56 P 3 HD1 P 3 HB2 −42.69 21.34 0 ovlp 56 P 3 HD2 P 3 HB2 −42.69 21.34 0 asgn 57 K 2 HE1 P 3 HG1 −32.35 16.18 0 ovlp 57 K 2 HE2 P 3 HG2 −32.35 16.18 0 ovlp 57 K 2 HE1 P 3 HG2 −32.35 16.18 0 ovlp 57 K 2 HE2 P 3 HG1 −32.35 16.18 0 asgn 58 P 3 HD1 P 3 HD1 2988.43 1494.21 0 ovlp 58 P 3 HD2 P 3 HD2 2988.43 1494.21 0 ovlp 58 P 3 HD2 P 3 HD1 2988.43 1494.21 0 ovlp 58 P 3 HD1 P 3 HD2 2988.43 1494.21 0 asgn 59 P 3 HA P 3 HD1 −16.06 8.03 0 ovlp 59 P 3 HA P 3 HD2 −16.06 8.03 0 asgn 60 F 1 HE1 P 3 HD1 8.77 4.39 0 ovlp 60 F 1 HE1 P 3 HD2 8.77 4.39 0 ovlp 60 F 1 HE2 P 3 HD1 8.77 4.39 0 ovlp 60 F 1 HZ1 P 3 HD2 8.77 4.39 0 ovlp 60 F 1 HZ2 P 3 HD2 8.77 4.39 0 ovlp 60 F 1 HE2 P 3 HD2 8.77 4.39 0 ovlp 60 F 1 HZ1 P 3 HD1 8.77 4.39 0 ovlp 60 F 1 HZ2 P 3 HD1 8.77 4.39 0 asgn 61 F 1 HH P 3 HD1 4.62 2.31 0 ovlp 61 F 1 HH P 3 HD2 4.62 2.31 0 asgn 62 K 2 HA P 3 HD1 −100.32 50.16 0 ovlp 62 K 2 HA P 3 HD2 −100.32 50.16 0 asgn 63 K 2 HB1 P 3 HD1 −145.35 72.67 0 ovlp 63 K 2 HB2 P 3 HD1 −145.35 72.67 0 ovlp 63 K 2 HB1 P 3 HD2 −145.35 72.67 0 ovlp 63 K 2 HB2 P 3 HD2 −145.35 72.67 0 asgn 64 K 2 HG1 P 3 HD1 −26.97 13.49 0 ovlp 64 K 2 HG2 P 3 HD2 −26.97 13.49 0 ovlp 64 K 2 HG1 P 3 HD2 −26.97 13.49 0 ovlp 64 K 2 HG2 P 3 HD1 −26.97 13.49 0 asgn 65 K 2 HD1 P 3 HD1 −26.95 13.48 0 ovlp 65 K 2 HD2 P 3 HD1 −26.95 13.48 0 ovlp 65 K 2 HD1 P 3 HD2 −26.95 13.48 0 ovlp 65 K 2 HD2 P 3 HD2 −26.95 13.48 0 asgn 66 K 2 HE1 P 3 HD1 −13.04 6.52 0 ovlp 66 K 2 HE1 P 3 HD2 −13.04 6.52 0 ovlp 66 K 2 HE2 P 3 HD2 −13.04 6.52 0 ovlp 66 K 2 HE2 P 3 HD1 −13.04 6.52 0 asgn 67 K 2 HA F 1 HB1 −2.66 1.79 0 ovlp 67 K 2 HA F 1 HB2 −2.66 1.79 0 remark noROEs asgn 101 P 3 HB2 F 1 HB1 0.00 0.41 0 ovlp 101 P 3 HB2 F 1 HB2 0.00 0.41 0 asgn 102 K 2 HG1 F 1 HB1 0.00 0.41 0 ovlp 102 K 2 HG1 F 1 HB2 0.00 0.41 0 ovlp 102 K 2 HG2 F 1 HB2 0.00 0.41 0 ovlp 102 K 2 HG2 F 1 HB1 0.00 0.41 0 asgn 103 K 2 HB1 F 1 HG1 0.00 0.58 0 ovlp 103 K 2 HB2 F 1 HG1 0.00 0.58 0 ovlp 103 K 2 HB1 F 1 HG2 0.00 0.58 0 ovlp 103 K 2 HB2 F 1 HG2 0.00 0.58 0 asgn 104 K 2 HB1 F 1 HE1 0.00 3.08 0 ovlp 104 K 2 HB2 F 1 HE1 0.00 3.08 0 ovlp 104 K 2 HB2 F 1 HE2 0.00 3.08 0 ovlp 104 K 2 HB2 F 1 HZ1 0.00 3.08 0 ovlp 104 K 2 HB1 F 1 HZ2 0.00 3.08 0 ovlp 104 K 2 HB1 F 1 HZ1 0.00 3.08 0 ovlp 104 K 2 HB1 F 1 HE2 0.00 3.08 0 ovlp 104 K 2 HB2 F 1 HZ2 0.00 3.08 0 asgn 105 K 2 HA F 1 HH 0.00 0.21 0 asgn 106 K 2 HE1 F 1 HH 0.00 0.21 0 ovlp 106 K 2 HE2 F 1 HH 0.00 0.21 0 asgn 107 P 3 HB1 F 1 HH 0.00 0.21 0 asgn 108 K 2 HB1 F 1 HH 0.00 0.21 0 ovlp 108 K 2 HB2 F 1 HH 0.00 0.21 0 asgn 109 K 2 HG1 F 1 HH 0.00 0.21 0 ovlp 109 K 2 HG2 F 1 HH 0.00 0.21 0 asgn 110 K 2 HD1 F 1 HH 0.00 0.21 0 ovlp 110 K 2 HD2 F 1 HH 0.00 0.21 0 asgn 111 F 1 HE1 K 2 HA 0.00 0.33 0 ovlp 111 F 1 HZ1 K 2 HA 0.00 0.33 0 ovlp 111 F 1 HE2 K 2 HA 0.00 0.33 0 ovlp 111 F 1 HZ2 K 2 HA 0.00 0.33 0 asgn 112 F 1 HH K 2 HA 0.00 0.33 0 asgn 113 P 3 HB1 K 2 HA 0.00 0.33 0 asgn 114 P 3 HB2 K 2 HA 0.00 0.33 0 asgn 115 P 3 HG1 K 2 HA 0.00 0.33 0 ovlp 115 P 3 HG2 K 2 HA 0.00 0.33 0 asgn 116 F 1 HH K 2 HG1 0.00 0.46 0 ovlp 116 F 1 HH K 2 HG2 0.00 0.46 0 asgn 117 P 3 HB1 K 2 HG1 0.00 0.46 0 ovlp 117 P 3 HB1 K 2 HG2 0.00 0.46 0 asgn 118 F 1 HB1 K 2 HG1 0.00 0.46 0 ovlp 118 F 1 HB1 K 2 HG2 0.00 0.46 0 ovlp 118 F 1 HB2 K 2 HG1 0.00 0.46 0 ovlp 118 F 1 HB2 K 2 HG2 0.00 0.46 0 asgn 119 P 3 HB2 K 2 HG1 0.00 0.46 0 ovlp 119 P 3 HB2 K 2 HG2 0.00 0.46 0 asgn 120 P 3 HB1 K 2 HD1 0.00 0.31 0 ovlp 120 P 3 HB1 K 2 HD2 0.00 0.31 0 asgn 121 F 1 HH K 2 HE1 0.00 0.20 0 ovlp 121 F 1 HH K 2 HE2 0.00 0.20 0 asgn 122 P 3 HB2 K 2 HE1 0.00 0.20 0 ovlp 122 P 3 HB2 K 2 HE2 0.00 0.20 0 asgn 123 F 1 HB1 P 3 HA 0.00 1.81 0 ovlp 123 F 1 HB2 P 3 HA 0.00 1.81 0 asgn 124 K 2 HA P 3 HB1 0.00 0.38 0 asgn 124 F 1 HA P 3 HB1 0.00 0.38 0 asgn 125 K 2 HE1 P 3 HB1 0.00 0.38 0 ovlp 125 K 2 HE2 P 3 HB1 0.00 0.38 0 asgn 126 F 1 HB1 P 3 HB1 0.00 0.38 0 ovlp 126 F 1 HB2 P 3 HB1 0.00 0.38 0 asgn 127 K 2 HB1 P 3 HB1 0.00 0.38 0 ovlp 127 K 2 HB2 P 3 HB1 0.00 0.38 0 asgn 128 K 2 HD1 P 3 HB1 0.00 0.38 0 ovlp 128 K 2 HD2 P 3 HB1 0.00 0.38 0 asgn 129 K 2 HG1 P 3 HB1 0.00 0.38 0 ovlp 129 K 2 HG2 P 3 HB1 0.00 0.38 0 asgn 130 K 2 HA P 3 HB2 0.00 0.45 0 asgn 130 F 1 HA P 3 HB2 0.00 0.45 0 asgn 131 K 2 HE1 P 3 HB2 0.00 0.45 0 ovlp 131 K 2 HE2 P 3 HB2 0.00 0.45 0 asgn 132 F 1 HG1 P 3 HB2 0.00 0.45 0 ovlp 132 F 1 HG2 P 3 HB2 0.00 0.45 0 asgn 133 F 1 HB1 P 3 HB2 0.00 0.45 0 ovlp 133 F 1 HB2 P 3 HB2 0.00 0.45 0 asgn 134 K 2 HD1 P 3 HB2 0.00 0.45 0 ovlp 134 K 2 HD2 P 3 HB2 0.00 0.45 0 asgn 135 K 2 HG1 P 3 HB2 0.00 0.45 0 ovlp 135 K 2 HG2 P 3 HB2 0.00 0.45 0 asgn 136 K 2 HA P 3 HG1 0.00 0.77 0 ovlp 136 K 2 HA P 3 HG2 0.00 0.77 0 asgn 137 F 1 HG1 P 3 HG1 0.00 0.77 0 ovlp 137 F 1 HG2 P 3 HG2 0.00 0.77 0 ovlp 137 F 1 HG2 P 3 HG1 0.00 0.77 0 ovlp 137 F 1 HG1 P 3 HG2 0.00 0.77 0 asgn 138 F 1 HB1 P 3 HG1 0.00 0.77 0 ovlp 138 F 1 HB2 P 3 HG1 0.00 0.77 0 ovlp 138 F 1 HB2 P 3 HG2 0.00 0.77 0 ovlp 138 F 1 HB1 P 3 HG2 0.00 0.77 0 asgn 139 P 3 HB1 F 1 HG1 0.00 0.58 0 ovlp 139 P 3 HB1 F 1 HG2 0.00 0.58 0 endsection

Scalar-Coupling Dataset for Lisinopril

remark Conformation-dependent scalar couplings configuration: field 600 solvent d2o ident JCOUP endsection data: remark atoms karplus c1 c2 c3 phase experimental error coup 1 2 HA 2 CA 2 CB 2 HB1 7.23 −1.37 2.22 0 6.0 0.5 0 coup 2 2 HA 2 CA 2 CB 2 HB2 7.23 −1.37 2.22 0 6.0 0.5 0 coup 3 1 HB1 1 CB 1 CA 1 HA 7.23 −1.37 2.22 0 6.2 0.5 0 coup 4 1 HB2 1 CB 1 CA 1 HA 7.23 −1.37 2.22 0 6.2 0.5 0 endsection

χ² _(restraint) Values for the Best Optimised Dynamic Structure of Lisinopril

104 K 2 HB1 F 1 HE1 0.00 3.10 −0.49 0.03 0.02 0 +7 2D-T-ROESY 130 K 2 HA P 3 HB2 0.00 0.45 0.05 0.03 0.04 0 +0 2D-T-ROESY 136 K 2 HA P 3 HG1 0.00 0.77 0.09 0.05 0.26 0 +1 2D-T-ROESY 114 P 3 HB2 K 2 HA 0.00 0.33 0.05 0.06 0.14 0 +0 2D-T-ROESY 112 F 1 HH K 2 HA 0.00 0.33 0.09 0.07 0.09 0 +0 2D-T-ROESY 116 F 1 HH K 2 HG1 0.00 0.46 0.12 0.07 0.09 0 +1 2D-T-ROESY 107 P 3 HB1 F 1 HH 0.00 0.21 0.05 0.08 0.36 0 +0 2D-T-ROESY 131 K 2 HE1 P 3 HB2 0.00 0.45 0.01 0.10 0.72 0 +1 2D-T-ROESY 126 F 1 HB1 P 3 HB1 0.00 0.38 0.01 0.10 1.40 0 +1 2D-T-ROESY 105 K 2 HA F 1 HH 0.00 0.21 0.09 0.16 0.53 0 +0 2D-T-ROESY 13 F 1 HE1 F 1 HG1 −160.00 82.00 −190.00 0.18 2.00 0 +7 2D-T-ROESY 29 K 2 HB1 K 2 HB1 980.00 490.00 1100.00 0.19 2.80 0 +3 2D-T-ROESY 18 F 1 HE1 F 1 HE1 13000.00 6700.00 11000.00 0.20 1.20 0 +15 2D-T-ROESY 15 K 2 HD1 F 1 HG1 −4.00 2.00 −3.50 0.20 2.10 0 +3 2D-T-ROESY 106 K 2 HE1 F 1 HH 0.00 0.21 0.10 0.22 1.10 0 +1 2D-T-ROESY 127 K 2 HB1 P 3 HB1 0.00 0.38 −0.10 0.24 3.00 0 +1 2D-T-ROESY 134 K 2 HD1 P 3 HB2 0.00 0.45 −0.05 0.24 11.00 0 +1 2D-T-ROESY 6 K 2 HA F 1 HA −24.00 12.00 −19.00 0.24 1.60 0 +0 2D-T-ROESY 46 P 3 HA P 3 HA 4200.00 2100.00 3200.00 0.25 1.90 0 +0 2D-T-ROESY 121 F 1 HH K 2 HE1 0.00 0.20 0.10 0.25 1.30 0 +1 2D-T-ROESY 133 F 1 HB1 P 3 HB2 0.00 0.45 −0.05 0.26 3.20 0 +1 2D-T-ROESY 115 P 3 HG1 K 2 HA 0.00 0.33 0.09 0.29 7.90 0 +1 2D-T-ROESY 1 3J 2 HA 3J 2 HB1 6.00 0.50 6.00 0.29 3.70 0 +0 JCOUP 3 K 2 HD1 P 3 HA −1.40 0.79 −1.70 0.31 4.30 0 +1 2D-T-ROESY 101 P 3 HB2 F 1 HB1 0.00 0.41 −0.05 0.31 4.50 0 +1 2D-T-ROESY 108 K 2 HB1 F 1 HH 0.00 0.21 0.12 0.31 2.00 0 +1 2D-T-ROESY 132 F 1 HG1 P 3 HB2 0.00 0.45 −0.21 0.32 3.30 0 +1 2D-T-ROESY 109 K 2 HG1 F 1 HH 0.00 0.21 0.12 0.32 2.10 0 +1 2D-T-ROESY 28 P 3 HD1 K 2 HA −48.00 24.00 −36.00 0.33 4.00 0 +1 2D-T-ROESY 40 K 2 HD1 K 2 HD1 1100.00 560.00 1400.00 0.33 5.10 0 +3 2D-T-ROESY 48 F 1 HA P 3 HA −12.00 5.80 −8.50 0.36 4.60 0 +0 2D-T-ROESY 64 K 2 HG1 P 3 HD1 −27.00 13.00 −23.00 0.36 6.80 0 +3 2D-T-ROESY 65 K 2 HD1 P 3 HD1 −27.00 13.00 −23.00 0.36 5.10 0 +3 2D-T-ROESY 8 K 2 HD1 F 1 HA −2.00 1.00 −1.80 0.36 7.40 0 +1 2D-T-ROESY 110 K 2 HD1 F 1 HH 0.00 0.21 0.13 0.37 2.80 0 +1 2D-T-ROESY 39 P 3 HD1 K 2 HG1 −28.00 14.00 −23.00 0.38 7.10 0 +3 2D-T-ROESY 42 F 1 HH K 2 HD1 −0.51 0.25 −0.40 0.39 6.70 0 +8 2D-T-ROESY 37 F 1 HE1 K 2 HG1 −0.49 0.24 −0.60 0.44 8.60 0 +7 2D-T-ROESY 35 K 2 HA K 2 HG1 −14.00 6.80 −9.60 0.44 7.00 0 +1 2D-T-ROESY 49 F 1 HE1 P 3 HA −11.00 5.60 −9.40 0.44 11.00 0 +3 2D-T-ROESY 67 K 2 HA F 1 HB1 −2.70 1.80 −1.50 0.45 5.50 0 +1 2D-T-ROESY 31 F 1 HE1 K 2 HB1 −0.65 0.32 −0.49 0.47 6.60 0 +7 2D-T-ROESY 1 F 1 HA K 2 HD1 −2.00 0.88 −1.80 0.47 13.00 0 +1 2D-T-ROESY 11 P 3 HA F 1 HB1 −2.20 1.10 −2.00 0.48 11.00 0 +1 2D-T-ROESY 44 P 3 HD1 K 2 HD1 −21.00 11.00 −23.00 0.49 12.00 0 +3 2D-T-ROESY 21 P 3 HA F 1 HE1 −13.00 6.30 −9.40 0.52 14.00 0 +3 2D-T-ROESY 122 P 3 HB2 K 2 HE1 0.00 0.20 0.01 0.52 19.00 0 +1 2D-T-ROESY 7 K 2 HB1 F 1 HA −5.10 2.50 −3.60 0.55 12.00 0 +1 2D-T-ROESY 9 P 3 HA F 1 HA −13.00 6.50 −8.50 0.55 8.60 0 +0 2D-T-ROESY 27 F 1 HB1 K 2 HA −1.30 0.64 −1.50 0.56 23.00 0 +1 2D-T-ROESY 119 P 3 HB2 K 2 HG1 0.00 0.46 0.17 0.56 16.00 0 +1 2D-T-ROESY 23 F 1 HH F 1 HH 13000.00 6400.00 8100.00 0.57 7.30 0 +0 2D-T-ROESY 135 K 2 HG1 P 3 HB2 0.00 0.45 0.17 0.59 18.00 0 +1 2D-T-ROESY 102 P 3 HB1 F 1 HG1 0.00 0.58 0.15 0.60 100.00 0 +1 2D-T-ROESY 30 F 1 HA K 2 HB1 −3.10 1.60 −3.60 0.62 16.00 0 +1 2D-T-ROESY 2 3J 2 HA 3J 2 HB2 6.00 0.50 5.80 0.65 20.00 0 +0 JCOUP 138 F 1 HB1 P 3 HG1 0.00 0.77 −0.45 0.66 18.00 0 +3 2D-T-ROESY 59 P 3 HA P 3 HD1 −16.00 8.00 −9.00 0.79 13.00 0 +1 2D-T-ROESY 43 P 3 HA K 2 HD1 −3.00 1.50 −1.70 0.80 15.00 0 +1 2D-T-ROESY 2 F 1 HG1 K 2 HD1 −2.40 1.40 −3.50 0.82 25.00 0 +3 2D-T-ROESY 47 P 3 HD1 P 3 HA −17.00 8.30 −9.00 0.86 15.00 0 +1 2D-T-ROESY 14 F 1 HG1 K 2 HG1 −2.90 0.88 −2.10 1.00 40.00 0 +3 2D-T-ROESY 4 3J 1 HB2 3J 1 HA 6.20 0.50 6.00 1.00 45.00 0 +0 JCOUP 56 P 3 HD1 P 3 HB2 −43.00 21.00 −22.00 1.00 22.00 0 +1 2D-T-ROESY 3 3J 1 HB1 3J 1 HA 6.20 0.50 5.70 1.10 37.00 0 +0 JCOUP 51 P 3 HB1 P 3 HB1 2700.00 1300.00 1200.00 1.20 27.00 0 +0 2D-T-ROESY 25 K 2 HG1 K 2 HA −6.60 3.30 −9.60 1.20 46.00 0 +1 2D-T-ROESY 12 F 1 HG1 F 1 HG1 3000.00 1500.00 1300.00 1.30 36.00 0 +3 2D-T-ROESY 123 F 1 HB1 P 3 HA 0.00 1.80 −2.00 1.30 50.00 0 +1 2D-T-ROESY 53 P 3 HD1 P 3 HB1 −32.00 16.00 −50.00 1.40 77.00 0 +1 2D-T-ROESY 117 P 3 HB1 K 2 HG1 0.00 0.46 0.19 1.40 100.00 0 +1 2D-T-ROESY 41 F 1 HE1 K 2 HD1 −0.81 0.40 −0.34 1.60 67.00 0 +7 2D-T-ROESY 62 K 2 HA P 3 HD1 −100.00 50.00 −36.00 1.70 55.00 0 +1 2D-T-ROESY 111 F 1 HE1 K 2 HA 0.00 0.33 −0.14 1.90 320.00 0 +3 2D-T-ROESY 58 P 3 HD1 P 3 HD1 3000.00 1500.00 940.00 1.90 68.00 0 +3 2D-T-ROESY 129 K 2 HG1 P 3 HB1 0.00 0.38 0.19 2.00 220.00 0 +1 2D-T-ROESY 128 K 2 HD1 P 3 HB1 0.00 0.38 0.28 2.10 270.00 0 +1 2D-T-ROESY 124 K 2 HA P 3 HB1 0.00 0.38 0.54 2.10 100.00 0 +0 2D-T-ROESY 38 P 3 HA K 2 HG1 −3.70 1.80 −0.95 2.20 97.00 0 +1 2D-T-ROESY 34 K 2 HG1 K 2 HG1 770.00 380.00 1300.00 2.20 120.00 0 +3 2D-T-ROESY 16 P 3 HA F 1 HG1 −4.90 2.50 −1.30 2.30 110.00 0 +1 2D-T-ROESY 118 F 1 HB1 K 2 HG1 0.00 0.46 −0.58 2.40 150.00 0 +3 2D-T-ROESY 26 F 1 HA K 2 HA −10.00 5.20 −19.00 2.70 170.00 0 +0 2D-T-ROESY 20 F 1 HG1 F 1 HE1 −100.00 52.00 −190.00 2.70 200.00 0 +7 2D-T-ROESY 36 K 2 HE1 K 2 HG1 −170.00 85.00 −29.00 2.80 150.00 0 +3 2D-T-ROESY 113 P 3 HB1 K 2 HA 0.00 0.33 0.54 2.80 180.00 0 +0 2D-T-ROESY 139 K 2 HG1 F 1 HB1 0.00 0.41 −0.58 3.00 240.00 0 +3 2D-T-ROESY 52 P 3 HA P 3 HB1 −200.00 100.00 −27.00 3.00 170.00 0 +0 2D-T-ROESY 103 K 2 HB1 F 1 HG1 0.00 0.58 −0.96 3.10 270.00 0 +3 2D-T-ROESY 120 P 3 HB1 K 2 HD1 0.00 0.31 0.28 3.20 600.00 0 +1 2D-T-ROESY 125 K 2 HE1 P 3 HB1 0.00 0.38 0.35 3.30 560.00 0 +1 2D-T-ROESY 33 P 3 HD1 K 2 HB1 −84.00 42.00 −5.90 3.50 240.00 0 +3 2D-T-ROESY 45 K 2 HE1 K 2 HE1 11000.00 5500.00 710.00 3.50 230.00 0 +3 2D-T-ROESY 17 P 3 HB2 F 1 HG1 −6.60 3.30 −0.21 3.70 270.00 0 +1 2D-T-ROESY 32 P 3 HA K 2 HB1 −24.00 12.00 −1.00 3.70 260.00 0 +1 2D-T-ROESY 137 F 1 HG1 P 3 HG1 0.00 0.77 −0.92 3.70 2400.00 0 +3 2D-T-ROESY 63 K 2 HB1 P 3 HD1 −150.00 73.00 −5.90 3.70 260.00 0 +3 2D-T-ROESY 61 F 1 HH P 3 HD1 4.60 2.30 0.12 3.80 270.00 0 +1 2D-T-ROESY 19 F 1 HA F 1 HE1 −11.00 5.40 −0.18 3.90 290.00 0 +3 2D-T-ROESY 4 F 1 HE1 F 1 HA −12.00 6.10 −0.18 3.90 290.00 0 +3 2D-T-ROESY 57 K 2 HE1 P 3 HG1 −32.00 16.00 −0.16 4.00 300.00 0 +3 2D-T-ROESY 55 F 1 HH P 3 HB1 −3.20 1.60 0.05 4.10 330.00 0 +0 2D-T-ROESY 22 P 3 HD1 F 1 HE1 −6.20 3.10 −0.22 4.10 370.00 0 +7 2D-T-ROESY 24 P 3 HA F 1 HH −19.00 9.60 0.53 4.20 340.00 0 +0 2D-T-ROESY 54 F 1 HE1 P 3 HB1 −4.20 2.10 0.11 4.20 350.00 0 +3 2D-T-ROESY 50 F 1 HH P 3 HA −6.50 3.30 0.53 4.70 450.00 0 +0 2D-T-ROESY 60 F 1 HE1 P 3 HD1 8.80 4.40 −0.97 5.50 1100.00 0 +7 2D-T-ROESY 66 K 2 HE1 P 3 HD1 −13.00 6.50 −16.00 5.50 2300.00 0 +3 2D-T-ROESY 10 P 3 HB1 F 1 HA −3.20 1.60 0.33 5.60 1000.00 0 +0 2D-T-ROESY 5 F 1 HH F 1 HA −2.00 0.99 0.44 5.90 670.00 0 +0 2D-T-ROESY

PDB Coordinates for the Best Mean Optimised Dynamic Structure of Lisinopril

ATOM 1 N PHE 1 0.066 0.786 1.247 1.00 0.00 MOLG ATOM 2 C PHE 1 −1.730 0.523 −0.373 1.00 0.00 MOLG ATOM 3 CA PHE 1 −1.353 0.399 1.109 1.00 0.00 MOLG ATOM 4 CB PHE 1 −2.329 1.285 1.912 1.00 0.00 MOLG ATOM 5 CG PHE 1 −3.769 0.715 1.634 1.00 0.00 MOLG ATOM 6 CD PHE 1 −4.933 1.397 2.300 1.00 0.00 MOLG ATOM 7 CE1 PHE 1 −5.526 2.440 1.599 1.00 0.00 MOLG ATOM 8 CZ1 PHE 1 −6.612 3.119 2.130 1.00 0.00 MOLG ATOM 9 CZ2 PHE 1 −6.520 1.712 4.080 1.00 0.00 MOLG ATOM 10 CE2 PHE 1 −5.433 1.030 3.548 1.00 0.00 MOLG ATOM 11 CH PHE 1 −7.112 2.755 3.374 1.00 0.00 MOLG ATOM 12 O1 PHE 1 −1.216 1.467 −1.086 1.00 0.00 MOLG ATOM 13 O2 PHE 1 −2.551 −0.310 −0.919 1.00 0.00 MOLG ATOM 14 HN1 PHE 1 0.150 1.760 0.923 1.00 0.00 MOLG ATOM 15 HN2 PHE 1 0.354 0.727 2.230 1.00 0.00 MOLG ATOM 16 HA PHE 1 −1.510 −0.612 1.481 1.00 0.00 MOLG ATOM 17 HB1 PHE 1 −2.102 1.198 2.984 1.00 0.00 MOLG ATOM 18 HB2 PHE 1 −2.251 2.335 1.600 1.00 0.00 MOLG ATOM 19 HG1 PHE 1 −3.996 0.695 0.563 1.00 0.00 MOLG ATOM 20 HG2 PHE 1 −3.789 −0.333 1.964 1.00 0.00 MOLG ATOM 21 HE1 PHE 1 −5.145 2.716 0.647 1.00 0.00 MOLG ATOM 22 HE2 PHE 1 −4.998 0.238 4.095 1.00 0.00 MOLG ATOM 23 HZ1 PHE 1 −7.060 3.915 1.587 1.00 0.00 MOLG ATOM 24 HZ2 PHE 1 −6.905 1.436 5.027 1.00 0.00 MOLG ATOM 25 HH PHE 1 −7.941 3.271 3.783 1.00 0.00 MOLG ATOM 26 NZ LYS 2 6.665 0.555 1.257 1.00 0.00 MOLG ATOM 27 C LYS 2 0.875 −1.664 0.831 1.00 0.00 MOLG ATOM 28 CA LYS 2 0.985 −0.133 0.401 1.00 0.00 MOLG ATOM 29 CB LYS 2 2.470 0.377 0.601 1.00 0.00 MOLG ATOM 30 CG LYS 2 2.982 0.361 2.069 1.00 0.00 MOLG ATOM 31 CD LYS 2 4.404 0.915 2.108 1.00 0.00 MOLG ATOM 32 CE LYS 2 5.297 0.034 1.230 1.00 0.00 MOLG ATOM 33 O LYS 2 1.499 −2.046 1.824 1.00 0.00 MOLG ATOM 34 HA LYS 2 0.718 −0.033 −0.656 1.00 0.00 MOLG ATOM 35 HB1 LYS 2 3.135 −0.253 −0.007 1.00 0.00 MOLG ATOM 36 HB2 LYS 2 2.528 1.415 0.243 1.00 0.00 MOLG ATOM 37 HG1 LYS 2 2.326 0.975 2.700 1.00 0.00 MOLG ATOM 38 HG2 LYS 2 3.002 −0.660 2.452 1.00 0.00 MOLG ATOM 39 HD1 LYS 2 4.406 1.942 1.716 1.00 0.00 MOLG ATOM 40 HD2 LYS 2 4.778 0.915 3.141 1.00 0.00 MOLG ATOM 41 HE1 LYS 2 4.920 0.051 0.196 1.00 0.00 MOLG ATOM 42 HE2 LYS 2 5.283 −0.996 1.609 1.00 0.00 MOLG ATOM 43 HZ1 LYS 2 6.673 1.520 0.898 1.00 0.00 MOLG ATOM 44 HZ2 LYS 2 7.269 −0.037 0.670 1.00 0.00 MOLG ATOM 45 HZ3 LYS 2 7.014 0.545 2.226 1.00 0.00 MOLG ATOM 46 N PRO 3 0.226 −2.717 0.070 1.00 0.00 MOLG ATOM 47 C PRO 3 1.442 −4.890 0.439 1.00 0.00 MOLG ATOM 48 CA PRO 3 0.171 −4.100 0.540 1.00 0.00 MOLG ATOM 49 CB PRO 3 −0.888 −4.661 −0.441 1.00 0.00 MOLG ATOM 50 CG PRO 3 −0.349 −4.064 −1.687 1.00 0.00 MOLG ATOM 51 CD PRO 3 −0.490 −2.596 −1.172 1.00 0.00 MOLG ATOM 52 O1 PRO 3 1.864 −5.514 1.421 1.00 0.00 MOLG ATOM 53 O2 PRO 3 2.089 −4.924 −0.675 1.00 0.00 MOLG ATOM 54 HA PRO 3 −0.216 −4.107 1.568 1.00 0.00 MOLG ATOM 55 HB1 PRO 3 −0.807 −5.753 −0.524 1.00 0.00 MOLG ATOM 56 HB2 PRO 3 −1.913 −4.371 −0.172 1.00 0.00 MOLG ATOM 57 HG1 PRO 3 0.681 −4.353 −1.931 1.00 0.00 MOLG ATOM 58 HG2 PRO 3 −1.030 −4.277 −2.526 1.00 0.00 MOLG ATOM 59 HD1 PRO 3 −1.498 −2.266 −1.076 1.00 0.00 MOLG ATOM 60 HD2 PRO 3 0.065 −1.908 −1.824 1.00 0.00 MOLG END

EXAMPLE 3 AngiotensinI

AngiotensinI is a natural decapeptide that causes blood vessels to constrict and drives blood pressure up. It is a decapeptide hormone (sequence DRVYIHPFHL) and a powerful dipsogen. It is derived from the precursor molecule angiotensinogen, a serum globulin produced in the liver, and plays an important role in the renin-angiotensin system. Angiotensin-converting enzyme (ACE) cleaves the two C-terminal residues from AngiotensinI to create AngiotensinII, which mediates these biological processes. In this worked example, we demonstrate how the dynamic 3D-solution structure of AngiotensinI was determined from experimental NMR data using the methodology according to the present invention.

Chemical Shift Assignment and Measurement of Homonuclear Scalar-Coupling Constants

The atoms and residues in AngiotensinI were given names according to XPLOR format (see Appendix C). All the NMR data on AngiotensinI was recorded at pH 6.0, which, in combination with the typical pK_(a) values, dictates the ionization state of most of the titratable groups in the molecule, namely: backbone N-terminal amine group, +ve; Asp1 sidechain, −ve; Arg2 sidechain, +ve; backbone C-terminal carboxylate, −ve. The two hisitidine sidechains (His6, His9) were given a +ve charge, consistent with their expected pK_(a) value (6.5), although further experimental data should be collected to determine if this is indeed the case. Partial conjugation of the lone pair of electrons from the proline residue's nitrogen atom with the adjacent carbonyl double-bond results in the presence of both cis and trans stereoisomers of AngiotensinI in solution.

The ¹H and ¹³C chemical shifts of both stereoisomers of AngiotensinI at 300 K were assigned using [¹H-¹H]-COSY, [¹H-¹H]-TOCSY and natural-abundance [¹H-¹³C]-HSQC spectra recorded at 600 MHz on a 5 mM NMR sample (5% D₂O, pH 6.0, 0.3 mM DSS) of AngiotensinI. By integration of peak volumes for resonances that were distinct for the cis and trans forms, the mole abundance ratio was determined to be 80% trans:20% cis. Since trans-AngiotensinI is more abundant in the mixture, it was decided at this stage to determine the dynamic 3D-structure of trans AngiotensinI. The measured proton chemical shifts for AngiotensinI are given in Table 2 below.

TABLE 2 Chemical shifts for AngiotensinI Shift (ppm)^(a) Residue Atom trans cis D1 HA 4.251 4.251 HB1 ^(b) 2.824 2.824 HB2 2.679 2.679 R2 HA 4.347 4.347 HB*^(c) 1.737 1.737 HG* 1.519 1.519 HD* 3.148 3.148 HE 7.115 7.115 V3 HN 8.234 8.234 HA 4.084 4.084 HB 1.969 1.969 HG1* 0.912 0.896 HH2* 0.866 0.851 Y4 HN 8.499 8.476 HA 4.593 4.593 HB* 2.921 ? HD* 7.087 7.087 HE* 6.759 6.759 I5 HN 8.028 8.112 HA 4.065 4.124 HB 1.710 1.710 HG11 1.378 1.378 HG12 1.091 1.091 HG2* 0.791 0.869 HD1* 0.797 0.865 H6 HN 8.371 8.148 HA 4.746 4.746 HB1 3.200 3.046 HB2 3.200 2.973 HD2 7.304 7.163 HE1 8.501 8.501 P7 HA 4.301 4.082 HB1 2.276 2.130 HB2 1.942 2.058 HG* 1.960 1.824 HD1 3.763 3.568 HD2 3.423 3.396 F8 HN 8.386 8.630 HA 4.590 4.481 HB* 3.050 3.125 HD* 7.208 7.169 HE* 7.323 7.276 HZ 7.278 7.278 H9 HN 8.050 7.869 HA 4.579 4.534 HB* 3.168 3.154 HD2 7.155 7.155 HE1 8.331 8.331 L10 HN 8.052 8.084 HA 4.141 4.091 HB* 1.584 1.556 HG 1.578 1.578 HD1* 0.925 0.925 HD2* 0.894 0.871 ^(a)All ¹H chemical shifts were determined at 300 K, pH 6.0 in 5% D₂O/90% H₂O, relative to internal DSS. ^(b)Chemical shifts in italics denote atoms that could not been stereospecifically assigned without reference to the local 3D structure. ^(c)Atoms with an asterisk denote degenerate chemical shitfts (e.g. HB* indicates that HB1 and HB2 have identical values).

Chemical shifts were also measured at 278K and 310 K and seen not to vary significantly (or, in the case of the amide protons, only vary linearly, see below), i.e., indicating that the conformation of the molecule is not noticeably perturbed over this temperature range.

With the exception of the HA and HN protons in trans AngiotensinI, most protons had complex spectral lineshapes due the large number of scalar-couplings present (as many as five ²J_(HH)/³J_(HH) scalar coupling in the arginine sidechain) and strong-coupling. This complexity prevented the measurement of most scalar-couplings in the sidechains. However, ³J_(HH) coupling constants were measured for various sidechain protons, as shown in the scalar-coupling restraint lists (see Appendix C).

Analysis of Spectral Lineshapes

A 2D [¹H, ¹H]-NOESY dataset was used to provide structural restraints for trans AngiotensinI. The value of λ (1.8 Hz) for this dataset was determined by measurement of resonances from NOEs to the Ile5 HN proton. All HN protons had simple doublet scaling factor sets (i.e. ƒ_(i)={2, 2}). Various aromatic ring protons had either no, one or two ³J scalar-couplings, and did not suffer from strong-coupling, and therefore also had ideal singlet (e.g. His6 HE1), doublet (e.g. Tyr4 HD*) or triplet lineshapes (e.g Phe8 HZ), respectively. Several HA protons (e.g. His6 HA) had basic quadruplet lineshapes because they had three ³J scalar couplings; in these cases the broadening formula was applied as described above. All other protons had complex lineshapes and suffered from strong-coupling—their scaling-factor sets were determined using the rules for strongly-coupled protons (see above).

To summarise, the scaling factor sets for each proton in trans AngiotensinI in this 2D [¹H, ¹H]-NOESY dataset were as follows:

Asp1 HN {2, 2} HA {4, 4, 4, 4} HB1 {4, 4, 4, 4} HB2 {4, 4, 4, 4} Arg2 HN {2, 2} HA {4, 2, 4} HB* {6.0, 3.0, 3.0, 6.0} HG* {15.0, 10.2, 7.7, 7.5, 9.1, 8.2, 6.8, 8.3, 13.5} HD* {2} [estimated] HE {2, 2} Val3 HN {2, 2} HA {4, 2.2 4} HB {16.4, 6.1, 3.7, 3.6, 6.1, 16.4} HG1* {2, 2} HG2* {2, 2} Tyr4 HN {2, 2} HA {8.0, 2.7, 2.7, 8.0} HB* {2, 2} HD* {2, 2} HE* {2, 2} Ile5 HN {2, 2} HA {4, 2.2, 4} HB {6.3, 3.4, 3.4, 6.3} HG11 {6.4, 3.3, 3.3, 5.6, 18.2} HG12 {15.7, 6.9, 4.4, 4.3, 4.9, 9.2, 47.7} HG2* {2, 2} HD1* {4, 2, 4} His6 HN {2, 2} HA {8.0, 2.7, 2.7, 8.0} HB1 {4, 4, 4, 4} HB2 {4, 4, 4, 4} HD2 {1} HE1 {1} Pro7 HA {4, 2.5, 4} HB1 {15.8, 5.4, 4.0, 4.0, 5.4, 15.8} HB2 {—} [shape too broadened and complex for analysis] HG* {12.6, 6.7, 4.9, 4.8, 6.4, 8.5, 11.6} HD1 {6.1, 3.0, 3.0, 6.1} HD2 {6.1, 3.0, 3.0, 6.1} Phe8 HN {2, 2} HA {8.0, 2.7, 2.7, 8.0} HB* {15.0, 11.2, 6.2, 5.5, 5.5, 6.2, 11.2, 15.0} HD* {2, 2} HE* {2, 2} HZ {4, 2, 4} His9 HN {2, 2} HA {9.6, 2.8, 2.7, 5.9} HB* {15.5, 13.2, 6.1, 5.3, 5.3, 6.1, 13.2, 15.5} HD2 {1} HE1 {1} Leu10 HN {2, 2} HA {8.0, 2.7, 2.7, 8.0} HB* {2.0} [estimated] HG {2.0} [estimated] HD1* {2, 2} HD2* {2, 2}

Measurement and Quantitation of NMR Spectra

All NMR spectra were recorded on a sample of 5 mM AngiotensinI (5% D₂O, pH 6.0, 0.3 mM DSS) at 600 MHz. Four different kinds of NMR data in six different experimental NMR datasets were used in the determination of the dynamic solution structure of trans AngiotensinI:

-   -   1) NOESY relaxation data: one experimental dataset, a 2D         [¹H-¹H]-NOESY     -   2) Conformation-dependent scalar couplings: three experimental         datasets     -   3) Dihedral angle restraints: one experimental dataset     -   4) Hydrogen bond restraints: one experimental dataset

The pertinent acquisition parameters for each of these different NMR datasets (and the number of structural restraints measured from them) were as follows:

1) The 2D [¹H, ¹H]-NOESY spectrum was recorded at 278 K with an NOE mixing time of 700 ms and sweep widths of 7200 Hz in both dimensions. Using the scaling-factor sets described above, 343 NOE and 382 noNOE structural restraints were measured from this spectrum. Errors on each NOE restraint were determined as described above, using the initial m value of 0.4 for a 2D [¹H, ¹H]-NOESY spectrum. The header for this file is given in Appendix C, while the NOE and noNOE structural restraints are detailed implicitly in the χ² _(restraint) file in Appendix C for the sake of brevity. 2) A total of 61 conformation-dependent scalar couplings were measured for HN protons, HA protons and the Ile5 CA-CB-CG1-CD1 dihedral angle from 1D, ¹⁵N-HSQC and ¹³C-HSQC spectra at 278K, 298K and 310K. These were organised into a separate scalar-coupling restraint file for each temperature, which are all given in Appendix C. 3) Dihedral angle restraints were generated using the chemical shifts shown in Table 2 and the program TALOS [42]. These predicted phi and psi backbone angles with their (doubled) error values were used in the dihedral angle restraints file given in Appendix C, which contained a total of 16 restraints. 4) The presence and absence of hydrogen bonds for amide groups in AngiotensinI were determined from amide proton chemical shift temperature coefficients. Temperature coefficients more negative than −4.6 ppb/K indicate the absence of any significant hydrogen bonding interactions involving the amide proton [44]. Values for temperature coefficients for amide protons for AngiotensinI were measured as described in Blundell and Almond (2007) [43]. Values were: Val3 (−8.9 ppb/K), Tyr4 (−9.4 ppb/K), Ile5 (−6.4 ppb/K), His6 (−8.9 ppb/K), Phe8 (−9.1 ppb/K) and Leu10 (−8.2 ppb/K) and all were therefore found to be more negative than −4.6 ppb/K, indicating that they make no significant hydrogen bonds (i.e., <˜10-20% of the time) in aqueous solution. Accordingly, 5 hydrogen bond restraints were included in the structure calculations in the file given in Appendix C.

Molecule Specification

All experimental datasets were acquired in H₂O. In H₂O, the N-terminal primary amine, Arg2 guanidino sidechain protons, Tyr4 hydroxyl proton, and both histidine sidechain amine protons in both His6 and His9 are in fast exchange. All these protons were therefore defined as NMR-inactive in the solvent mask file as follows:

remark Solvent mask for AngiotensinI conditions: solvents 1 endsection solvent: name h2o add * H* exc 1 HN* exc 2 HH* exc 4 HH exc 6 HD1 exc 6 HE2 exc 9 HD1 exc 9 HE2 endsection

The locations of the two oxygen atoms in the carboxylate groups in AngiotensinI (i.e., Asp1 sidechain & C-terminus), the Arg2 guanidino group and Tyr4 hydroxyl proton relative to the rest of the molecular structure could not be specified from the experimental data. These atoms were therefore set to be van der Waals inactive, as detailed in the following van der Waals input file:

remark Van der Waals mask for AngiotensinI configuration: vdw.cutoff 6.0 vdw.coupling 1e−4 endsection nonbonded: remark: include all atoms vdw * H* 0.016 0.60 vdw * C* 0.100 1.91 vdw * N* 0.170 1.82 vdw * O* 0.210 1.66 remark: then exclude these atoms exc 1 OD* exc 2 HH* exc 2 NH1 exc 2 NH2 exc 2 CZ exc 2 NE exc 2 HE exc 4 HH exc 10 OE* endsection

Experimental Data Input

The value of τ_(c) has not been precisely measured experimentally for trans AngiotensinI. Therefore, a value of 0.4 ns for τ_(c) was used as an estimate. After a few rounds of structure calculations, it was apparent that the molecule was adopting a highly-extended shape and that a symmetric top anisotropic model was likely to be more appropriate. By repeated rounds of calculation for a constant set of 2D-NOESY data, this was indeed found to be the case, with a considerably better fit to the experimental data being achieved with this anisotropic model. The best fit to the experimental data (i.e. lowest χ² _(total)) was found with a perpendicular τ_(c) value of 1.2 and a parallel τ_(c) value of 0.5 ns. All the experimental data files used in the structure calculations are detailed in Appendix C.

Dynamic Model

The pertinent conformationally-flexible bonds and chemistries within AngiotensinI were identified, using the methodology described above:

1) Phi (φ, N^(i)-CA^(i)), psi (φ, CA^(i)-C^(i)) and omega (ω, C^(i)-N^(i+1)) single bonds for each residue, comprising the backbone of the molecule. 2) Two single bonds in the Asp1 sidechain can rotate (CA-CB, CB-CG). 3) Four single bonds in the Arg2 sidechain can rotate (CA-CB, CB-CG, CG-CD, CD-NE). 4) Three single bonds in the Val3 sidechain can rotate (CA-CB, CB-CG1, CB-CG2). 5) Three single bonds in the Tyr4 sidechain can rotate (CA-CB, CB-CG, OH-HH). 6) Four single bonds in the Ile5 sidechain can rotate (CA-CB, CB-CG1, CG1-CD1, CB-CG2). 7) Two single bonds in the His6 sidechain can rotate (CA-CB, CB-CG). 8) The Pro7 ring adopts two major conformations in solution, as described above for lisinopril. 9) Two single bonds in the Phe8 sidechain can rotate (CA-CB, CB-CG). 10) Two single bonds in the His9 sidechain can rotate (CA-CB, CB-CG). 11) Four single bonds in the Leu10 sidechain can rotate (CA-CB, CB-CG, CG-CD1, CG-CD2).

To create a realistic dynamic model of the molecule that could be used to optimise against the observed experimental data, the above degrees of freedom were modelled in the dynamic model file as follows:

1) The majority of backbone phi and psi bonds are between sp²- and sp³-hybridised atoms and therefore take a bimodal model in the first instance. All the backbone omega bonds were represented with a fixed unimodal model, taking the mean dihedral angle appropriate for a trans geometry, i.e. 180°. The N-terminal amine bond (Asp1 N-CA) is between two sp³-hybridised atoms and therefore takes a trimodal model to represent the rotation of the amine group. 2) The CA-CB bond (also called chi1, χ1) in the Asp1 sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The three rotamer states (gt, tg, gg) were specified with three different variables (var 11, 12, 13) and given the same Gaussian spread (var 14) on each rotamer position. The initial partition used to seed the three rotamer states was estimated from the difference in ³J coupling constants between the HA and HB1/HB2 protons. The CB-CG bond (also called chit, χ2) in the Asp1 sidechain is sp²- and sp³-hybridised atoms and therefore takes a bimodal model. 3) The CA-CB, CB-CG and CG-CD bonds (χ1, χ2, χ3) in the Arg2 sidechain are between sp³-hybridised atoms and therefore take trimodal models. For each bond, the three rotamer states (gt, tg, gg) were specified with three different variables and given the same Gaussian spread on each rotamer position. The CD-NE bond (χ4) in the Arg2 sidechain is between sp²- and sp³-hybridised atoms and therefore takes a bimodal model. 4) The CA-CB bond (also called chi 1, χ1) in the Val3 sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The three rotamer states (gt, tg, gg) were specified with three different variables and given the same Gaussian spread on each rotamer position. The initial partition used to seed the three rotamer states was estimated from the ³J coupling constants between the HA and HB protons. The two methyl groups are connected by bonds CB-CG1 and CB-CG2, which are between two sp³-hybridised atoms. These were both given a trimodal model to represent the rotation of the methyl groups. 5) The CA-CB bond (χ1) in the Tyr sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The CB-CG bond (χ2) is between sp²- and sp³-hybridised atoms and therefore takes a bimodal model. The OH-HH bond takes a unimodal model. 6) All the bonds within the Ile5 sidechain are between sp³-hybridised atoms and therefore take trimodal models. The initial partitions used to seed the three rotamer states for the CA-CB and CB-CG1 bonds were estimated from the HA-HB, HB-HG12 and HB-HG13 ³J coupling constants. 7) The CA-CB bond (χ1) in the His6 sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The CB-CG bond (χ2) is between sp²- and sp³-hybridised atoms and therefore takes a bimodal model. 8) The two conformations for the Proline ring were represented in an identical fashion to that used for lisinopril above. 9) The CA-CB bond (χ1) in the Phe8 sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The CB-CG bond (χ2) is between sp²- and sp³-hybridised atoms and therefore takes a bimodal model. 10) The CA-CB bond (χ1) in the His9 sidechain is between sp³-hybridised atoms and therefore takes a trimodal model. The CB-CG bond (χ2) is between sp²- and sp³-hybridised atoms and therefore takes a bimodal model. 11) All the bonds within the Leu10 sidechain are between sp³-hybridised atoms and therefore take trimodal models.

The specific implementation of these considerations was achieved with the dynamic model file given below (see Appendix C for the associated internal coordinates table).

remark Dynamic model of AngiotensinI variables: remark D1 remark D1 phi (N-terminus) var 1 fix 60 jump 0.0 start 0.0 var 2 fix 300 jump 0.0 start 0.0 var 3 fix 180 jump 0.0 start 0.0 var 4 fix 20 jump 0.0 start 0.0 remark D1 psi var 5 rand 0 360 jump 180.0 start 0.0 var 6 fix 15 jump 5.0 start 0.0 var 7 rand 0 360 jump 180.0 start 0.0 var 8 fix 15 jump 5.0 start 0.0 remark D1 omega var 9 fix 180 jump 0.0 start 0.0 var 10 fix 0.0 jump 0.0 start 0.0 remark D1 chi1 var 11 fix 60 jump 0.0 start 0.0 var 12 fix 300 jump 0.0 start 0.0 var 13 fix 180 jump 0.0 start 0.0 var 14 fix 20 jump 5.0 start 0.0 remark D1 chi2 var 15 rand 0 360 jump 180.0 start 0.0 var 16 rand 0 360 jump 180.0 start 0.0 var 17 fix 20 jump 0.0 start 0.0 remark R2 remark R2 phi var 18 rand 0 360 jump 180.0 start 0.0 var 19 fix 15 jump 5.0 start 0.0 var 20 rand 0 360 jump 180.0 start 0.0 var 21 fix 15 jump 5.0 start 0.0 remark R2 psi var 22 rand 0 360 jump 180.0 start 0.0 var 23 fix 15 jump 5.0 start 0.0 var 24 rand 0 360 jump 180.0 start 0.0 var 25 fix 15 jump 5.0 start 0.0 remark R2 omega var 26 fix 180 jump 0.0 start 0.0 var 27 fix 0.0 jump 0.0 start 0.0 remark R2 chi1 var 28 fix 60 jump 0.0 start 0.0 var 29 fix 300 jump 0.0 start 0.0 var 30 fix 180 jump 0.0 start 0.0 var 31 fix 20 jump 5.0 start 0.0 remark R2 chi2 var 32 fix 60 jump 0.0 start 0.0 var 33 fix 300 jump 0.0 start 0.0 var 34 fix 180 jump 0.0 start 0.0 var 35 fix 20 jump 5.0 start 0.0 remark R2 chi3 var 36 fix 60 jump 0.0 start 0.0 var 37 fix 300 jump 0.0 start 0.0 var 38 fix 180 jump 0.0 start 0.0 var 39 fix 20 jump 5.0 start 0.0 remark R2 chi4 var 40 rand 0 360 jump 180.0 start 0.0 var 41 rand 0 360 jump 180.0 start 0.0 var 42 fix 20 jump 5.0 start 0.0 remark V3 remark V3 phi var 43 rand 0 360 jump 180.0 start 0.0 var 44 fix 15 jump 5.0 start 0.0 var 45 rand 0 360 jump 180.0 start 0.0 var 46 fix 15 jump 5.0 start 0.0 remark V3 psi var 47 rand 0 360 jump 180.0 start 0.0 var 48 fix 15 jump 5.0 start 0.0 var 49 rand 0 360 jump 180.0 start 0.0 var 50 fix 15 jump 5.0 start 0.0 remark V3 omega var 51 fix 180 jump 0.0 start 0.0 var 52 fix 0.0 jump 0.0 start 0.0 remark V3 chi1 var 53 fix 60 jump 0.0 start 0.0 var 54 fix 300 jump 0.0 start 0.0 var 55 fix 180 jump 0.0 start 0.0 var 56 fix 20 jump 5.0 start 0.0 remark V3 chi2 methyl CG2 var 57 fix 60 jump 0.0 start 0.0 var 58 fix 300 jump 0.0 start 0.0 var 59 fix 180 jump 0.0 start 0.0 var 60 fix 20 jump 0.0 start 0.0 remark V3 chi3 methyl CG1 var 61 fix 60 jump 0.0 start 0.0 var 62 fix 300 jump 0.0 start 0.0 var 63 fix 180 jump 0.0 start 0.0 var 64 fix 20 jump 0.0 start 0.0 remark Y4 remark Y4 phi var 65 rand 0 360 jump 180.0 start 0.0 var 66 fix 15 jump 5.0 start 0.0 var 67 rand 0 360 jump 180.0 start 0.0 var 68 fix 15 jump 5.0 start 0.0 remark Y4 psi var 69 rand 0 360 jump 180.0 start 0.0 var 70 fix 15 jump 5.0 start 0.0 var 71 rand 0 360 jump 180.0 start 0.0 var 72 fix 15 jump 5.0 start 0.0 remark Y4 omega var 73 fix 180 jump 0.0 start 0.0 var 74 fix 0.0 jump 0.0 start 0.0 remark Y4 chi1 var 75 fix 60 jump 0.0 start 0.0 var 76 fix 300 jump 0.0 start 0.0 var 77 fix 180 jump 0.0 start 0.0 var 78 fix 20 jump 5.0 start 0.0 remark Y4 chi2 var 79 rand 0 360 jump 180.0 start 0.0 var 80 rand 0 360 jump 180.0 start 0.0 var 81 fix 20 jump 5.0 start 0.0 remark Y4 chi3 hydroxyl var 82 rand 0 360 jump 180.0 start 0.0 var 83 fix 20 jump 0.0 start 0.0 remark I5 remark I5 phi var 84 rand 0 360 jump 180.0 start 0.0 var 85 fix 15 jump 5.0 start 0.0 var 86 rand 0 360 jump 180.0 start 0.0 var 87 fix 15 jump 5.0 start 0.0 remark I5 psi var 88 rand 0 360 jump 180.0 start 0.0 var 89 fix 15 jump 5.0 start 0.0 var 90 rand 0 360 jump 180.0 start 0.0 var 91 fix 15 jump 5.0 start 0.0 remark I5 omega var 92 fix 180 jump 0.0 start 0.0 var 93 fix 0.0 jump 0.0 start 0.0 remark I5 chi1 var 94 fix 60 jump 0.0 start 0.0 var 95 fix 300 jump 0.0 start 0.0 var 96 fix 180 jump 0.0 start 0.0 var 97 fix 20 jump 5.0 start 0.0 remark I5 chi2 var 98 fix 60 jump 0.0 start 0.0 var 99 fix 300 jump 0.0 start 0.0 var 100 fix 180 jump 0.0 start 0.0 var 101 fix 20 jump 5.0 start 0.0 remark I5 chi3 methyl CD1 var 102 fix 60 jump 0.0 start 0.0 var 103 fix 300 jump 0.0 start 0.0 var 104 fix 180 jump 0.0 start 0.0 var 105 fix 20 jump 0.0 start 0.0 remark I5 chi4 methyl CG2 var 106 fix 60 jump 0.0 start 0.0 var 107 fix 300 jump 0.0 start 0.0 var 108 fix 180 jump 0.0 start 0.0 var 109 fix 20 jump 0.0 start 0.0 remark H6 remark H6 phi var 110 rand 0 360 jump 180.0 start 0.0 var 111 fix 15 jump 5.0 start 0.0 var 112 rand 0 360 jump 180.0 start 0.0 var 113 fix 15 jump 5.0 start 0.0 remark H6 psi var 114 rand 0 360 jump 180.0 start 0.0 var 115 fix 15 jump 5.0 start 0.0 var 116 rand 0 360 jump 180.0 start 0.0 var 117 fix 15 jump 5.0 start 0.0 remark H6 omega TRANS PROLINE var 118 fix 0 jump 0.0 start 0.0 var 119 fix 0.0 jump 0.0 start 0.0 remark H6 chi1 var 120 fix 60 jump 0.0 start 0.0 var 121 fix 300 jump 0.0 start 0.0 var 122 fix 180 jump 0.0 start 0.0 var 123 fix 20 jump 5.0 start 0.0 remark H6 chi2 var 124 rand 0 360 jump 180.0 start 0.0 var 125 rand 0 360 jump 180.0 start 0.0 var 126 fix 20 jump 5.0 start 0.0 remark P7 remark P7 psi var 127 rand 0 360 jump 180.0 start 0.0 var 128 fix 15 jump 5.0 start 0.0 var 129 rand 0 360 jump 180.0 start 0.0 var 130 fix 15 jump 5.0 start 0.0 remark P7 omega var 131 fix 180 jump 0.0 start 0.0 var 132 fix 0.0 jump 0.0 start 0.0 remark P7 ring flip remark N state = gamma exo = UP var 133 fix −167.15 jump 0.0 start 0.0 var 134 fix −54.52 jump 0.0 start 0.0 var 135 fix 58.07 jump 0.0 start 0.0 var 136 fix −48.96 jump 0.0 start 0.0 var 137 fix −157.04 jump 0.0 start 0.0 remark S state = gamma endo = DOWN var 138 fix 167.46 jump 0.0 start 0.0 var 139 fix 45.29 jump 0.0 start 0.0 var 140 fix −55.99 jump 0.0 start 0.0 var 141 fix 46.66 jump 0.0 start 0.0 var 142 fix 157.82 jump 0.0 start 0.0 remark dynamics var 143 fix 0.0 jump 0.0 start 0.0 remark F8 remark F8 phi var 144 rand 0 360 jump 180.0 start 0.0 var 145 fix 15 jump 5.0 start 0.0 var 146 rand 0 360 jump 180.0 start 0.0 var 147 fix 15 jump 5.0 start 0.0 remark F8 psi var 148 rand 0 360 jump 180.0 start 0.0 var 149 fix 15 jump 5.0 start 0.0 var 150 rand 0 360 jump 180.0 start 0.0 var 151 fix 15 jump 5.0 start 0.0 remark F8 omega var 152 fix 180 jump 0.0 start 0.0 var 153 fix 0.0 jump 0.0 start 0.0 remark F8 chi1 var 154 fix 60 jump 0.0 start 0.0 var 155 fix 300 jump 0.0 start 0.0 var 156 fix 180 jump 0.0 start 0.0 var 157 fix 20 jump 5.0 start 0.0 remark F8 chi2 var 158 rand 0 360 jump 180.0 start 0.0 var 159 rand 0 360 jump 180.0 start 0.0 var 160 fix 20 jump 5.0 start 0.0 remark H9 remark H9 phi var 161 rand 0 360 jump 180.0 start 0.0 var 162 fix 15 jump 5.0 start 0.0 var 163 rand 0 360 jump 180.0 start 0.0 var 164 fix 15 jump 5.0 start 0.0 remark H9 psi var 165 rand 0 360 jump 180.0 start 0.0 var 166 fix 15 jump 5.0 start 0.0 var 167 rand 0 360 jump 180.0 start 0.0 var 168 fix 15 jump 5.0 start 0.0 remark H9 omega var 169 fix 180 jump 0.0 start 0.0 var 170 fix 0.0 jump 0.0 start 0.0 remark H9 chi1 var 171 fix 60 jump 0.0 start 0.0 var 172 fix 300 jump 0.0 start 0.0 var 173 fix 180 jump 0.0 start 0.0 var 174 fix 20 jump 5.0 start 0.0 remark H9 chi2 var 175 rand 0 360 jump 180.0 start 0.0 var 176 rand 0 360 jump 180.0 start 0.0 var 177 fix 20 jump 5.0 start 0.0 remark L10 remark L10 phi var 178 rand 0 360 jump 180.0 start 0.0 var 179 fix 15 jump 5.0 start 0.0 var 180 rand 0 360 jump 180.0 start 0.0 var 181 fix 15 jump 5.0 start 0.0 remark L10 psi (C-terminus) var 182 rand 0 360 jump 180.0 start 0.0 var 183 rand 0 360 jump 180.0 start 0.0 var 184 fix 15 jump 0.0 start 0.0 remark L10 chi1 var 185 fix 60 jump 0.0 start 0.0 var 186 fix 300 jump 0.0 start 0.0 var 187 fix 180 jump 0.0 start 0.0 var 188 fix 20 jump 5.0 start 0.0 remark L10 chi2 var 189 fix 60 jump 0.0 start 0.0 var 190 fix 300 jump 0.0 start 0.0 var 191 fix 180 jump 0.0 start 0.0 var 192 fix 20 jump 5.0 start 0.0 remark L10 chi3 methyl CD1 var 193 fix 60 jump 0.0 start 0.0 var 194 fix 300 jump 0.0 start 0.0 var 195 fix 180 jump 0.0 start 0.0 var 196 fix 20 jump 0.0 start 0.0 remark L10 chi4 methyl CD2 var 197 fix 60 jump 0.0 start 0.0 var 198 fix 300 jump 0.0 start 0.0 var 199 fix 180 jump 0.0 start 0.0 var 200 fix 20 jump 0.0 start 0.0 endsection probabilities: remark D1 remark D1 phi (N-terminus) mode 1 3 0.33 0.66 0.0 remark D1 psi mode 2 2 0.5 0.1 remark D1 chi1 mode 3 3 0.09 0.29 0.05 remark D1 chi2 mode 4 2 0.5 0.1 remark R2 remark R2 phi mode 5 2 0.5 0.1 remark R2 psi mode 6 2 0.5 0.1 remark R2 chi1 mode 7 3 0.33 0.66 0.0 remark R2 chi2 mode 8 3 0.33 0.66 0.1 remark R2 chi3 mode 9 3 0.33 0.66 0.1 remark R2 chi4 mode 10 2 0.5 0.1 remark V3 remark V3 phi mode 11 2 0.5 0.1 remark V3 psi mode 12 2 0.5 0.1 remark V3 chi1 mode 13 3 0.15 0.30 0.05 remark V3 chi2 methyl CG2 mode 14 3 0.33 0.66 0.0 remark V4 chi3 methyl CG1 mode 15 3 0.33 0.66 0.0 remark Y4 remark Y4 phi mode 16 2 0.5 0.1 remark Y4 psi mode 17 2 0.5 0.1 remark Y4 chi1 mode 18 3 0.33 0.66 0.0 remark Y4 chi2 mode 19 2 0.5 0.0 remark I5 remark I5 phi mode 20 2 0.5 0.1 remark I5 psi mode 21 2 0.5 0.1 remark I5 chi1 mode 22 3 0.10 0.20 0.05 remark I5 chi2 mode 23 3 0.33 0.89 0.05 remark I5 chi3 methyl CD1 mode 24 3 0.33 0.66 0.0 remark I5 chi4 methyl CG2 mode 25 3 0.33 0.66 0.0 remark H6 remark H6 phi mode 26 2 0.5 0.1 remark H6 psi mode 27 2 0.5 0.1 remark H6 chi1 mode 28 3 0.13 0.81 0.05 remark H6 chi2 mode 29 2 0.5 0.1 remark P7 remark P7 psi mode 30 2 0.5 0.1 remark P7 ring mode 31 2 0.5 0.0 remark F8 remark F8 phi mode 32 2 0.5 0.1 remark F8 psi mode 33 2 0.5 0.1 remark F8 chi1 mode 34 3 0.33 0.66 0.1 remark F8 chi2 mode 35 2 0.5 0.0 remark H9 remark H9 phi mode 36 2 0.5 0.1 remark H9 psi mode 37 2 0.5 0.1 remark H9 chi1 mode 38 3 0.33 0.66 0.1 remark H9 chi2 mode 39 2 0.5 0.1 remark L10 remark L10 phi mode 40 2 0.5 0.1 remark L10 psi (C-terminus) mode 41 2 0.5 0.1 remark L10 chi1 mode 42 3 0.33 0.66 0.1 remark L10 chi2 mode 43 4 0.33 0.1 remark L10 chi3 methyl CD1 mode 44 3 0.33 0.66 0.0 remark L10 chi4 methyl CD2 mode 45 3 0.33 0.66 0.0 endsection dynamics: remark D1 remark D1 phi (N-terminus) multigyrate 1 1 1 4 2 4 3 4 remark D1 psi multigyrate 11 2 5 6 7 6 remark D1 omega gyrate 13 9 10 remark D1 chi1 multigyrate 6 3 11 14 12 14 13 14 remark D1 chi2 multigyrate 9 4 15 17 16 17 remark R2 remark R2 phi multigyrate 15 5 18 19 20 19 remark R2 psi multigyrate 35 6 22 23 24 23 remark R2 omega gyrate 37 26 27 remark R2 chi1 multigyrate 18 7 28 31 29 31 30 31 remark R2 chi2 multigyrate 21 8 32 35 33 35 34 35 remark R2 chi3 multigyrate 24 9 36 39 37 39 38 39 remark R2 chi4 multigyrate 27 10 40 42 41 42 remark V3 remark V3 phi multigyrate 39 11 43 44 45 43 remark V3 psi multigyrate 51 12 47 48 49 48 remark V3 omega gyrate 53 51 52 remark V3 chi1 multigyrate 42 13 53 56 54 56 55 56 remark V3 chi2 methyl CG2 multigyrate 45 14 57 60 58 60 59 60 remark V3 chi3 methyl CG1 multigyrate 48 15 61 64 62 64 63 64 remark Y4 remark Y4 phi multigyrate 55 16 65 66 67 66 remark Y4 psi multigyrate 75 17 69 70 71 70 remark Y4 omega gyrate 77 73 74 remark Y4 chi1 multigyrate 58 18 75 78 76 78 77 78 remark Y4 chi2 multigyrate 61 19 79 81 80 81 remark Y4 chi3 hydroxyl gyrate 69 82 83 remark I5 remark I5 phi multigyrate 79 20 84 85 86 85 remark I5 psi multigyrate 94 21 88 89 90 89 remark I5 omega gyrate 96 92 93 remark I5 chi1 multigyrate 82 22 94 97 95 97 96 97 remark I5 chi2 multigyrate 88 23 98 101 99 101 100 101 remark I5 chi3 methyl CD1 multigyrate 91 24 102 105 103 105 104 105 remark I5 chi4 methyl CG2 multigyrate 85 25 106 109 107 109 108 109 remark H6 remark H6 phi multigyrate 98 26 110 111 112 111 remark H6 psi multigyrate 115 27 114 115 116 115 remark H6 omega gyrate 117 118 119 remark H6 chi1 multigyrate 101 28 120 123 121 123 122 123 remark H6 chi2 multigyrate 104 29 124 126 125 126 remark P7 remark P7 psi multigyrate 132 30 127 128 129 128 remark P7 omega gyrate 134 131 132 remark P7 ring flip multigyrate 122 31 133 143 138 143 multigyrate 125 31 134 143 139 143 multigyrate 131 31 135 143 140 143 multigyrate 128 31 136 143 141 143 multigyrate 119 31 137 143 142 143 remark F8 remark F8 phi multigyrate 136 32 144 145 146 145 remark F8 psi multigyrate 155 33 148 149 150 149 remark F8 omega gyrate 157 152 153 remark F8 chi1 multigyrate 139 34 154 157 155 157 156 157 remark F8 chi2 multigyrate 142 35 158 160 159 160 remark H9 remark H9 phi multigyrate 159 36 161 162 163 162 remark H9 psi multigyrate 176 37 165 166 167 166 remark H9 omega gyrate 178 169 170 remark H9 chi1 multigyrate 162 38 171 174 172 174 173 174 remark H9 chi2 multigyrate 165 39 175 177 176 177 remark L10 remark L10 phi multigyrate 180 40 178 179 180 179 remark L10 psi (C-terminus) multigyrate 195 41 182 184 183 184 remark L10 chi1 multigyrate 183 42 185 188 186 188 187 188 remark L10 chi2 multigyrate 186 43 189 192 190 192 191 192 remark L10 chi3 methyl CD1 multigyrate 189 44 193 196 194 196 195 196 remark L10 chi4 methyl CD2 multigyrate 192 45 197 200 198 200 199 200 endsection

In this manner, all the flexible parts of the trans AngiotensinI molecule and their behaviour were fully defined as required for the computer implementation of the ensemble-generation algorithm according to the present invention.

Structure Calculations

Each round of structure calculations for trans AngiotensinI comprised 480 runs; a larger number than that used for lisinopril (100) was chosen because of the greater number of degrees of freedom being modelled. Statistics were performed on the lowest 15 χ² _(total) runs. Each individual run had 5,000 iteration steps initially and the dynamic ensemble was composed of 200 structures; a larger number than that used for α-HA₆ (40) was chosen because of the greater number of bi- and trimodal models used in the dynamic model file.

One of the challenges presented by this peptide arose from the large number of initially stereochemically ambiguous protons. While the chemical shifts of all protons at stereogenic centres within the molecule had been assigned, the identity of which proton was proR and which was proS could not be determined simply from the assignment spectra collected. Therefore, while unique and specific structural restraints (including both scalar coupling and NOE data) to stereospecifically ambiguous protons could be resolved, they could not be included in the structural calculations until this ambiguity had been solved. Some of these stereocentres could be readily determined by consideration of local NOEs and scalar coupling constants without the more detailed 3D knowledge gained from structure calculations:

1) Val3 HG1*/HG2*: the coupling constant between HA and HB indicated that HA and HB protons had a strong preference to be trans to each other, which meant that one methyl group was on average closer to protons within Tyr4 while the other was on average closer to Arg2. Comparison of NOE intensities between protons in Tyr4 and Arg2 to both Val3 methyl groups therefore allowed the two methyl groups to be easily stereospecifically assigned. 2) Pro7 HD1/HD2: Comparison of NOE intensities between the Pro7 HA proton and both HD protons, which are both at a fixed distance from Pro7 HA, allowed the two HD protons to be immediately stereospecifically assigned.

The scalar-coupling, dihedral angle and hydrogen bond restraint files (see Appendix C) had high confidence and were used almost in their entirety from the first round of structure calculations. A base dataset (167 NOE and 44 noNOE structural restraints) for the 2D [¹H, ¹H]-NOESY dataset was established over the first 30 rounds of structure calculations, after which point the structures loosely converged to preferred regions of the Ramachandran plot for all residues. The secondary statistics table at this point was as follows:

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 283 479.4 1.7 1 0 JCOUP 21 6.2 0.8 0 0 2D-NOESY 167 380.6 2.3 1 1 2D-NOE (no) 44 11.6 0.3 0 0 J5DEGC 20 22.8 1.1 0 0 HBOND 5 2.8 0.6 0 0 TDIHEDRALS 16 39.5 2.5 0 0 J15DEGC 9 6.1 0.7 0 0

In this case, it can be seen that the Chi/Res values are similar for the datasets, indicating that no one datasat is particularly dominating the results from the structure calculations. Indeed, the higher values observed for the 2D-NOESY dataset were understood to be due to the suboptimal value for the correlation time, and the relatively crude searching of conformational space afforded by the small number of iteration steps (5,000). At this point, it was clear that the peptide was adopting a grossly-extended conformation and therefore an anisotropic model would be more suitable. Screening a range of values for both perpendicular and parallel correlation times for a symmetric top model for AngiotensinI showed that values of 1.2 ns (perpendicular) and 0.5 ns (parallel) gave considerably better χ² _(dataset) scores for the 2D-NOESY data than the original symmetric model with correlation time 0.4 ns, and these were used throughout the remaining rounds of calculations. In addition, 10,000 iterative steps were used to allow the structure to be optimised more effectively.

Over the next 30 rounds of structure calculations, more NOE structural restraints (total 277) and many noNOE (total 225) structure restraints were included following the iterative method of weeding out incorrectly analysed and artefactual data described above. At this point, excellent convergence of the structures was being achieved, and the secondary statistics table was as follows:

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 557 937.3 1.7 0 0 JCOUP 24 31.6 1.3 0 0 2D-NOESY 270 753.4 2.8 0 0 2D-NOE (no) 208 71.5 0.3 0 0 J5DEGC 24 30.5 1.3 0 0 HBOND 5 3.0 0.6 0 0 TDIHEDRALS 17 35.3 2.1 0 0 J15DEGC 9 12.0 1.3 0 0

During this process, as the structures became more resolved, it became possible to stereospecifically assign the remaining sterochemically ambiguous protons as follows:

1) Pro7 HB1/HB2: Comparison of NOE intensities between protons in Phe8 and Ile5 to both Pro7 HB protons allowed the two HB protons to be easily stereospecifically assigned, because the structures were showing that one face of the proline ring faces Phe8 while the other faces Ile5. 2) Asp1 HB1/HB2, Ile5 HG11/HG12, His6 HB1/HB2, Leu10 HD1*/HD2*: these protons were stereospecifically assigned by running rounds of calculations for all 32 possible combinations with the same data and comparing the χ² _(total) scores. Considerable differences in χ² _(total) between these rounds gave a very high confidence for the stereospecific assignment of the Ile5 HG1*and His6 HB* protons, and a good confidence for the stereospecific assignment of the Asp1 HB* and Leu10 HD* protons.

Over the next 15 rounds of structure calculations, the remaining NOE and noNOE restraints were included until the 2D [¹H, ¹H]-NOESY dataset had been completely analysed. At this point, the secondary statistics table was as follows:

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 807 1417.2 1.8 5 1 JCOUP 26 46.6 1.8 0 0 2D-NOESY 343 1120.1 3.3 4 1 2D-NOE (no) 382 150.0 0.4 1 0 J5DEGC 26 39.3 1.5 0 0 HBOND 5 1.4 0.3 0 0 TDIHEDRALS 16 43.9 2.7 0 0 J15DEGC 9 15.9 1.8 0 0

Since the inclusion of the additional data in these 15 rounds (250 structural restraints) relative to the previous rounds did not appreciably alter the optimised dynamic structure, the dynamic structure was deemed to have been solved to a first approximation.

Structure Refinement

The dynamic 3D-solution structure of AngiotensinI was refined using a dynamic-model file, in which the starting values for the variables were taken from the results of the last round above. This allowed the optimisation algorithm to explore this specific χ² _(total) minimum quite effectively. The ensemble size was increased and more iteration steps were performed. The secondary statistics table after structure refinement was as follows:

Dataset Restraints Tot Chi Chi/Res Viol(>10) Percent TOTAL 807 1110.3 1.4 3 1 JCOUP 26 33.4 1.3 0 0 2D-NOESY 343 885.7 2.6 3 1 2D-NOE (no) 382 115.3 0.3 0 0 J5DEGC 26 43.5 1.7 0 0 HBOND 5 0.8 0.2 0 0 TDIHEDRALS 16 21.8 1.4 0 0 J15DEGC 9 9.8 1.1 0 0

Only 3 structural restraints have a χ² _(restraint) value greater than 10.0, which all relate to the Leu10 sidechain. This indicates that the calculated structure for this sidechain is somewhat inconsistent with the experimental data here for some reason. It is most likely that this inconsistency is due to the poor scaling factors for the Leu10 HB* and HG protons, which had to be estimated because of line broadening caused by strong coupling between Leu10 HB* and HG. Further experimental data is required to determine the structure of the Leu10 sidechain more precisely. The final list of all 807 structural restraints with their individual χ² restraint values is given in Appendix C. Several visual representations of the mean dynamic structure and dynamic ensemble of structures for AngiotensinI are given in FIGS. 30-31.

APPENDIX C AngiotensinI

Starting PDB 3D-coordinates for AngiotensinI

ATOM 1 N ASP 1 −16.312 −2.194 1.677 1.00 0.00 N ATOM 2 HN1 ASP 1 −16.934 −2.998 1.894 1.00 0.00 H ATOM 3 HN2 ASP 1 −16.799 −1.541 1.031 1.00 0.00 H ATOM 4 HN3 ASP 1 −16.069 −1.695 2.557 1.00 0.00 H ATOM 5 CA ASP 1 −15.069 −2.690 1.033 1.00 0.00 C ATOM 6 HA ASP 1 −14.603 −3.350 1.750 1.00 0.00 H ATOM 7 CB ASP 1 −15.425 −3.464 −0.273 1.00 0.00 C ATOM 8 HB1 ASP 1 −16.219 −4.211 −0.050 1.00 0.00 H ATOM 9 HB2 ASP 1 −15.825 −2.761 −1.034 1.00 0.00 H ATOM 10 CG ASP 1 −14.222 −4.223 −0.848 1.00 0.00 C ATOM 11 OD1 ASP 1 −13.815 −3.908 −1.998 1.00 0.00 O ATOM 12 OD2 ASP 1 −13.697 −5.123 −0.139 1.00 0.00 O ATOM 13 C ASP 1 −14.144 −1.537 0.747 1.00 0.00 C ATOM 14 O ASP 1 −14.577 −0.405 0.530 1.00 0.00 O ATOM 15 N ARG 2 −12.824 −1.825 0.742 1.00 0.00 N ATOM 16 HN ARG 2 −12.495 −2.746 0.935 1.00 0.00 H ATOM 17 CA ARG 2 −11.806 −0.864 0.421 1.00 0.00 C ATOM 18 HA ARG 2 −12.201 −0.128 −0.266 1.00 0.00 H ATOM 19 CB ARG 2 −11.197 −0.179 1.672 1.00 0.00 C ATOM 20 HB1 ARG 2 −12.022 0.318 2.230 1.00 0.00 H ATOM 21 HB2 ARG 2 −10.760 −0.950 2.343 1.00 0.00 H ATOM 22 CG ARG 2 −10.127 0.885 1.365 1.00 0.00 C ATOM 23 HG1 ARG 2 −9.291 0.407 0.808 1.00 0.00 H ATOM 24 HG2 ARG 2 −10.578 1.663 0.711 1.00 0.00 H ATOM 25 CD ARG 2 −9.554 1.544 2.628 1.00 0.00 C ATOM 26 HD1 ARG 2 −10.349 2.078 3.191 1.00 0.00 H ATOM 27 HD2 ARG 2 −9.079 0.777 3.276 1.00 0.00 H ATOM 28 NE ARG 2 −8.513 2.542 2.212 1.00 0.00 N ATOM 29 HE ARG 2 −8.434 2.774 1.242 1.00 0.00 H ATOM 30 CZ ARG 2 −7.656 3.133 3.101 1.00 0.00 C ATOM 31 NH2 ARG 2 −6.723 4.019 2.644 1.00 0.00 N ATOM 32 HH22 ARG 2 −6.091 4.455 3.286 1.00 0.00 H ATOM 33 HH21 ARG 2 −6.668 4.228 1.668 1.00 0.00 H ATOM 34 NH1 ARG 2 −7.720 2.850 4.434 1.00 0.00 N ATOM 35 HH12 ARG 2 −7.086 3.291 5.069 1.00 0.00 H ATOM 36 HH11 ARG 2 −8.401 2.202 4.775 1.00 0.00 H ATOM 37 C ARG 2 −10.744 −1.658 −0.273 1.00 0.00 C ATOM 38 O ARG 2 −10.421 −2.772 0.139 1.00 0.00 O ATOM 39 N VAL 3 −10.180 −1.082 −1.359 1.00 0.00 N ATOM 40 HN VAL 3 −10.487 −0.192 −1.686 1.00 0.00 H ATOM 41 CA VAL 3 −9.067 −1.644 −2.079 1.00 0.00 C ATOM 42 HA VAL 3 −8.700 −2.528 −1.576 1.00 0.00 H ATOM 43 CB VAL 3 −9.372 −1.965 −3.538 1.00 0.00 C ATOM 44 HB VAL 3 −9.686 −1.043 −4.076 1.00 0.00 H ATOM 45 CG2 VAL 3 −8.115 −2.538 −4.231 1.00 0.00 C ATOM 46 HG21 VAL 3 −8.359 −2.834 −5.273 1.00 0.00 H ATOM 47 HG22 VAL 3 −7.300 −1.785 −4.269 1.00 0.00 M ATOM 48 HG23 VAL 3 −7.749 −3.433 −3.686 1.00 0.00 H ATOM 49 CG1 VAL 3 −10.544 −2.969 −3.590 1.00 0.00 C ATOM 50 HG11 VAL 3 −10.749 −3.259 −4.643 1.00 0.00 H ATOM 51 HG12 VAL 3 −10.294 −3.885 −3.014 1.00 0.00 H ATOM 52 HG13 VAL 3 −11.469 −2.523 −3.169 1.00 0.00 H ATOM 53 C VAL 3 −8.034 −0.562 −1.986 1.00 0.00 C ATOM 54 O VAL 3 −8.273 0.575 −2.392 1.00 0.00 O ATOM 55 N TYR 4 −6.863 −0.903 −1.406 1.00 0.00 N ATOM 56 HN TYR 4 −6.685 −1.831 −1.089 1.00 0.00 H ATOM 57 CA TYR 4 −5.815 0.048 −1.164 1.00 0.00 C ATOM 58 HA TYR 4 −5.763 0.736 −1.998 1.00 0.00 H ATOM 59 CB TYR 4 −6.017 0.809 0.183 1.00 0.00 C ATOM 60 HB1 TYR 4 −6.994 1.336 0.154 1.00 0.00 H ATOM 61 HB2 TYR 4 −6.040 0.089 1.029 1.00 0.00 H ATOM 62 CG TYR 4 −4.958 1.853 0.447 1.00 0.00 C ATOM 63 CD1 TYR 4 −4.835 2.977 −0.388 1.00 0.00 C ATOM 64 HD1 TYR 4 −5.522 3.113 −1.211 1.00 0.00 H ATOM 65 CE1 TYR 4 −3.817 3.915 −0.176 1.00 0.00 C ATOM 66 HE1 TYR 4 −3.730 4.767 −0.834 1.00 0.00 M ATOM 67 CZ TYR 4 −2.910 3.739 0.879 1.00 0.00 C ATOM 68 OH TYR 4 −1.869 4.672 1.084 1.00 0.00 O ATOM 69 HH TYR 4 −1.354 4.380 1.840 1.00 0.00 H ATOM 70 CD2 TYR 4 −4.051 1.694 1.510 1.00 0.00 C ATOM 71 HD2 TYR 4 −4.128 0.832 2.156 1.00 0.00 H ATOM 72 CE2 TYR 4 −3.032 2.629 1.726 1.00 0.00 C ATOM 73 HE2 TYR 4 −2.338 2.485 2.541 1.00 0.00 H ATOM 74 C TYR 4 −4.547 −0.756 −1.126 1.00 0.00 C ATOM 75 O TYR 4 −4.547 −1.935 −0.774 1.00 0.00 O ATOM 76 N ILE 5 −3.427 −0.097 −1.491 1.00 0.00 N ATOM 77 HN ILE 5 −3.468 0.847 −1.809 1.00 0.00 N ATOM 78 CA ILE 5 −2.103 −0.633 −1.357 1.00 0.00 C ATOM 79 HA ILE 5 −2.086 −1.305 −0.509 1.00 0.00 H ATOM 80 CB ILE 5 −1.593 −1.374 −2.597 1.00 0.00 C ATOM 81 HB ILE 5 −2.292 −2.227 −2.768 1.00 0.00 H ATOM 82 CG2 ILE 5 −1.658 −0.481 −3.859 1.00 0.00 C ATOM 83 HG21 ILE 5 −1.408 −1.075 −4.763 1.00 0.00 H ATOM 84 HG22 ILE 5 −2.676 −0.064 −4.001 1.00 0.00 H ATOM 85 HG23 ILE 5 −0.934 0.357 −3.787 1.00 0.00 H ATOM 86 CG1 ILE 5 −0.191 −1.988 −2.352 1.00 0.00 C ATOM 87 HG11 ILE 5 0.558 −1.172 −2.260 1.00 0.00 H ATOM 88 HG12 ILE 5 −0.213 −2.539 −1.386 1.00 0.00 H ATOM 89 CD1 ILE 5 0.263 −2.955 −3.450 1.00 0.00 C ATOM 90 HD1 ILE 5 1.241 −3.407 −3.180 1.00 0.00 H ATOM 91 HD2 ILE 5 −0.479 −3.772 −3.576 1.00 0.00 H ATOM 92 HD3 ILE 5 0.379 −2.426 −4.419 1.00 0.00 H ATOM 93 C ILE 5 −1.270 0.569 −1.010 1.00 0.00 C ATOM 94 O ILE 5 −1.438 1.646 −1.582 1.00 0.00 O ATOM 95 N HIS 6 −0.369 0.410 −0.013 1.00 0.00 N ATOM 96 HN HIS 6 −0.259 −0.465 0.452 1.00 0.00 H ATOM 97 CA HIS 6 0.496 1.464 0.447 1.00 0.00 C ATOM 98 HA HIS 6 0.019 2.414 0.257 1.00 0.00 H ATOM 99 CB HIS 6 0.790 1.352 1.963 1.00 0.00 C ATOM 100 HB1 HIS 6 −0.176 1.341 2.513 1.00 0.00 H ATOM 101 HB2 HIS 6 1.305 0.390 2.177 1.00 0.00 H ATOM 102 CD2 HIS 6 2.918 2.493 2.907 1.00 0.00 C ATOM 103 HD2 HIS 6 3.646 1.691 2.944 1.00 0.00 H ATOM 104 CG HIS 6 1.625 2.479 2.509 1.00 0.00 C ATOM 105 NE2 HIS 6 3.213 3.778 3.275 1.00 0.00 N ATOM 106 HE2 HIS 6 4.098 4.103 3.610 1.00 0.00 H ATOM 107 ND1 HIS 6 1.149 3.756 2.640 1.00 0.00 N ATOM 108 HD1 HIS 6 0.225 4.064 2.408 1.00 0.00 H ATOM 109 CE1 HIS 6 2.128 4.521 3.104 1.00 0.00 C ATOM 110 HE1 HIS 6 2.054 5.569 3.308 1.00 0.00 H ATOM 111 C HIS 6 1.794 1.313 −0.312 1.00 0.00 C ATOM 112 O HIS 6 2.284 0.187 −0.390 1.00 0.00 O ATOM 113 N PRO 7 2.402 2.351 −0.889 1.00 0.00 N ATOM 114 CD PRO 7 1.819 3.685 −1.040 1.00 0.00 C ATOM 115 HD1 PRO 7 0.970 3.620 −1.755 1.00 0.00 H ATOM 116 HD2 PRO 7 1.472 4.084 −0.064 1.00 0.00 H ATOM 117 CA PRO 7 3.666 2.228 −1.594 1.00 0.00 C ATOM 118 HA PRO 7 3.654 1.355 −2.233 1.00 0.00 H ATOM 119 CB PRO 7 3.793 3.536 −2.391 1.00 0.00 C ATOM 120 HB1 PRO 7 3.336 3.386 −3.394 1.00 0.00 H ATOM 121 HB2 PRO 7 4.840 3.873 −2.521 1.00 0.00 H ATOM 122 CG PRO 7 2.943 4.549 −1.616 1.00 0.00 H ATOM 123 HG1 PRO 7 2.565 5.367 −2.260 1.00 0.00 C ATOM 124 HG2 PRO 7 3.544 4.976 −0.783 1.00 0.00 H ATOM 125 C PRO 7 4.782 2.094 −0.587 1.00 0.00 C ATOM 126 O PRO 7 4.741 2.757 0.449 1.00 0.00 O ATOM 127 N PHE 8 5.765 1.214 −0.872 1.00 0.00 N ATOM 128 HN PHE 8 5.773 0.693 −1.722 1.00 0.00 H ATOM 129 CA PHE 8 6.845 0.944 0.036 1.00 0.00 C ATOM 130 HA PHE 8 7.085 1.848 0.581 1.00 0.00 H ATOM 131 CB PHE 8 6.508 −0.225 1.009 1.00 0.00 C ATOM 132 HB1 PHE 8 5.586 0.029 1.575 1.00 0.00 H ATOM 133 HB2 PHE 8 6.316 −1.158 0.437 1.00 0.00 H ATOM 134 CG PHE 8 7.597 −0.479 2.025 1.00 0.00 C ATOM 135 CD1 PHE 8 7.892 0.477 3.012 1.00 0.00 C ATOM 136 HD1 PHE 8 7.327 1.397 3.056 1.00 0.00 H ATOM 137 CE1 PHE 8 8.917 0.250 3.939 1.00 0.00 C ATOM 138 HE1 PHE 8 9.138 0.992 4.692 1.00 0.00 H ATOM 139 CZ PHE 8 9.658 −0.937 3.888 1.00 0.00 C ATOM 140 HZ PHE 8 10.450 −1.111 4.601 1.00 0.00 H ATOM 141 CD2 PHE 8 8.347 −1.669 1.985 1.00 0.00 C ATOM 142 HD2 PHE 8 8.139 −2.410 1.227 1.00 0.00 H ATOM 143 CE2 PHE 8 9.372 −1.898 2.911 1.00 0.00 C ATOM 144 HE2 PHE 8 9.944 −2.813 2.868 1.00 0.00 H ATOM 145 C PHE 8 8.017 0.579 −0.828 1.00 0.00 C ATOM 146 O PHE 8 7.865 −0.085 −1.853 1.00 0.00 O ATOM 147 N HIS 9 9.223 1.012 −0.398 1.00 0.00 N ATOM 148 HN HIS 9 9.302 1.585 0.414 1.00 0.00 H ATOM 149 CA HIS 9 10.475 0.603 −0.973 1.00 0.00 C ATOM 150 HA HIS 9 10.315 −0.163 −1.720 1.00 0.00 H ATOM 151 CB HIS 9 11.287 1.773 −1.578 1.00 0.00 C ATOM 152 HB1 HIS 9 10.697 2.229 −2.403 1.00 0.00 H ATOM 153 HB2 HIS 9 11.443 2.557 −0.805 1.00 0.00 H ATOM 154 CD2 HIS 9 13.876 1.667 −1.688 1.00 0.00 C ATOM 155 HD2 HIS 9 14.194 2.300 −0.869 1.00 0.00 H ATOM 156 CG HIS 9 12.630 1.363 −2.123 1.00 0.00 C ATOM 157 NE2 HIS 9 14.758 0.995 −2.491 1.00 0.00 N ATOM 158 HE2 HIS 9 15.756 1.019 −2.413 1.00 0.00 H ATOM 159 ND1 HIS 9 12.771 0.507 −3.182 1.00 0.00 N ATOM 160 HD1 HIS 9 12.024 0.091 −3.702 1.00 0.00 H ATOM 161 CE1 HIS 9 14.066 0.303 −3.385 1.00 0.00 C ATOM 162 HE1 HIS 9 14.485 −0.323 −4.146 1.00 0.00 H ATOM 163 C HIS 9 11.244 0.015 0.171 1.00 0.00 C ATOM 164 O HIS 9 11.283 0.586 1.260 1.00 0.00 O ATOM 165 N LEU 10 11.869 −1.160 −0.066 1.00 0.00 N ATOM 166 HN LEU 10 11.815 −1.605 −0.957 1.00 0.00 H ATOM 167 CA LEU 10 12.662 −1.850 0.920 1.00 0.00 C ATOM 168 HA LEU 10 12.303 −1.587 1.906 1.00 0.00 H ATOM 169 CB LEU 10 12.568 −3.389 0.756 1.00 0.00 C ATOM 170 HB1 LEU 10 11.493 −3.621 0.576 1.00 0.00 H ATOM 171 HB2 LEU 10 13.124 −3.720 −0.146 1.00 0.00 H ATOM 172 CG LEU 10 13.003 −4.231 1.984 1.00 0.00 C ATOM 173 HG LEU 10 12.496 −3.798 2.877 1.00 0.00 H ATOM 174 CD1 LEU 10 12.499 −5.681 1.845 1.00 0.00 C ATOM 175 HD11 LEU 10 12.757 −6.267 2.752 1.00 0.00 H ATOM 176 HD12 LEU 10 11.396 −5.696 1.717 1.00 0.00 H ATOM 177 HD13 LEU 10 12.966 −6.168 0.963 1.00 0.00 H ATOM 178 CD2 LEU 10 14.520 −4.216 2.260 1.00 0.00 C ATOM 179 HD21 LEU 10 14.758 −4.891 3.109 1.00 0.00 H ATOM 180 HD22 LEU 10 15.078 −4.564 1.365 1.00 0.00 H ATOM 181 HD23 LEU 10 14.866 −3.197 2.526 1.00 0.00 H ATOM 182 C LEU 10 14.104 −1.354 0.736 1.00 0.00 C ATOM 183 OE1 LEU 10 14.697 −1.629 −0.341 1.00 0.00 O ATOM 184 OE2 LEU 10 14.621 −0.684 1.669 1.00 0.00 O END

Internal Coordinate Table for AngiotensinI

1 1 HN1 1 N 1 CA 1 CB 1.03942 109.453 58.9129 109.747 1.55931 2 1 HN1 1 CA 1 *N 1 HN2 1.03942 109.453 −120.095 109.412 1.03966 3 1 HN1 1 CA 1 *N 1 HN3 1.03942 109.453 119.982 109.357 1.04041 4 1 CB 1 N 1 *CA 1 C 1.55931 109.747 122.578 109.926 1.5056 5 1 CB 1 N 1 *CA 1 HA 1.55931 109.747 −119.466 106.098 1.08021 6 1 N 1 CA 1 CB 1 CG 1.48519 109.747 −169.346 112.361 1.53425 7 1 CG 1 CA 1 *CB 1 HB1 1.53425 112.361 119.292 109.165 1.11273 8 1 CG 1 CA 1 *CB 1 HB2 1.53425 112.361 −122.649 109.995 1.11055 9 1 CA 1 CB 1 CG 1 OD1 1.55931 112.361 −118.346 118.144 1.25991 10 1 OD1 1 CB 1 *CG 1 OD2 1.25991 118.144 179.802 117.974 1.26028 11 1 N 1 CA 1 C 2 N 1.48519 109.926 151.281 115.958 1.35106 12 2 N 1 CA 1 *C 1 O 1.35106 115.958 179.877 121.432 1.23126 13 1 CA 1 C 2 N 2 CA 1.5056 115.958 176.706 123.414 1.43628 14 2 CA 1 C 2 *N 2 HN 1.43628 123.414 −177.835 121.243 0.996861 15 1 C 2 N 2 CA 2 CB 1.35106 123.414 95.2178 113.178 1.55084 16 2 CB 2 N 2 *CA 2 C 1.55084 113.178 118.81 104.573 1.49663 17 2 CB 2 N 2 *CA 2 HA 1.55084 113.178 −124.378 109.782 1.08152 18 2 N 2 CA 2 CB 2 CG 1.43628 113.178 −178.484 114.66 1.53988 19 2 CG 2 CA 2 *CB 2 HB1 1.53988 114.66 120.313 108.092 1.1131 20 2 CG 2 CA 2 *CB 2 HB2 1.53988 114.66 −122.984 109.569 1.1116 21 2 CA 2 CB 2 CG 2 CD 1.55084 114.66 179.723 113.07 1.53551 22 2 CD 2 CB 2 *CG 2 HG1 1.53551 113.07 120.623 108.972 1.11249 23 2 CD 2 CB 2 *CG 2 HG2 1.53551 113.07 −121.823 108.595 1.11194 24 2 CB 2 CG 2 CD 2 NE 1.53988 113.07 179.157 108.434 1.50091 25 2 NE 2 CG 2 *CD 2 HD1 1.50091 108.434 119 110.861 1.11092 26 2 NE 2 CG 2 *CD 2 HD2 1.50091 108.434 −119.052 110.064 1.11077 27 2 CG 2 CD 2 NE 2 CZ 1.53551 108.434 −168.57 122.77 1.36896 28 2 CZ 2 CD 2 *NE 2 HE 1.36896 122.77 179.059 118.534 1.00048 29 2 CD 2 NE 2 CZ 2 NH2 1.50091 122.77 179.135 119.377 1.36541 30 2 NH2 2 NE 2 *CZ 2 NH1 1.36541 119.377 −179.978 121.039 1.36421 31 2 NE 2 CZ 2 NH2 2 HH22 1.36896 119.377 −179.893 119.965 1.00084 32 2 HH22 2 CZ 2 *NH2 2 HH21 1.00084 119.965 179.655 120.003 0.999641 33 2 NE 2 CZ 2 NH1 2 HH12 1.36896 121.039 179.996 119.956 0.999831 34 2 HH12 2 CZ 2 *NH1 2 HH11 0.999831 119.956 179.984 119.973 0.999973 35 2 N 2 CA 2 C 3 N 1.43628 104.573 138.359 116.251 1.3525 36 3 N 2 CA 2 *C 2 O 1.3525 116.251 −179.862 120.74 1.23088 37 2 CA 2 C 3 N 3 CA 1.49663 116.251 174.351 123.894 1.4398 38 3 CA 2 C 3 *N 3 HN 1.4398 123.894 −176.413 121.018 0.996633 39 2 C 3 N 3 CA 3 CB 1.3525 123.894 119.093 113.958 1.52471 40 3 CB 3 N 3 *CA 3 C 1.52471 113.958 119.468 102.707 1.49882 41 3 CB 3 N 3 *CA 3 HA 1.52471 113.958 −124.297 110.418 1.08127 42 3 N 3 CA 3 CB 3 CG2 1.4398 113.958 179.011 110.147 1.54552 43 3 CG2 3 CA 3 *CB 3 CG1 1.54552 110.147 122.039 108.72 1.54412 44 3 CG2 3 CA 3 *CB 3 HB 1.54552 110.147 −119.849 110.161 1.11271 45 3 CA 3 CB 3 CG2 3 HG21 1.52471 110.147 176.212 109.931 1.11037 46 3 HG21 3 CB 3 *CG2 3 HG22 1.11037 109.931 119.598 111.157 1.11026 47 3 HG21 3 CB 3 *CG2 3 HG23 1.11037 109.931 −119.679 110.302 1.10996 48 3 CA 3 CB 3 CG1 3 HG11 1.52471 108.72 −177.029 109.975 1.11128 49 3 HG11 3 CB 3 *CG1 3 HG12 1.11128 109.975 119.705 110.363 1.11055 50 3 HG11 3 CB 3 *CG1 3 HG13 1.11128 109.975 −119.575 111.01 1.10986 51 3 N 3 CA 3 C 4 N 1.4398 102.707 121.471 116.229 1.35053 52 4 N 3 CA 3 *C 3 O 1.35053 116.229 −178.282 120.838 1.23074 53 3 CA 3 C 4 N 4 CA 1.49882 116.229 −175.637 122.552 1.43571 54 4 CA 3 C 4 *N 4 HN 1.43571 122.552 177.834 121.772 0.996673 55 3 C 4 N 4 CA 4 CB 1.35053 122.552 85.1621 111.968 1.56024 56 4 CB 4 N 4 *CA 4 C 1.56024 111.968 120.078 105.423 1.50189 57 4 CB 4 N 4 *CA 4 HA 1.56024 111.968 −123.467 109.04 1.08241 58 4 N 4 CA 4 CB 4 CG 1.43571 111.968 −177.97 113.408 1.51034 59 4 CG 4 CA 4 *CB 4 HB1 1.51034 113.408 119.045 108.835 1.11045 60 4 CG 4 CA 4 *CB 4 HB2 1.51034 113.408 −122.736 110.118 1.11115 61 4 CA 4 CB 4 CG 4 CD1 1.56024 113.408 64.7325 120.682 1.40561 62 4 CD1 4 CB 4 *CG 4 CD2 1.40561 120.682 −178.013 120.409 1.40638 63 4 CB 4 CG 4 CD1 4 CE1 1.51034 120.682 −177.278 120.617 1.4004 64 4 CE1 4 CG 4 *CD1 4 HD1 1.4004 120.617 179.069 119.83 1.08065 65 4 CG 4 CD1 4 CE1 4 CZ 1.40561 120.617 −0.13183 119.999 1.40237 66 4 CZ 4 CD1 4 *CE1 4 HE1 1.40237 119.999 179.432 119.652 1.08002 67 4 CD1 4 CE1 4 CZ 4 OH 1.4004 119.999 179.028 120.186 1.41287 68 4 OH 4 CE1 4 *CZ 4 CE2 1.41287 120.186 −179.553 119.85 1.40157 69 4 CE1 4 CZ 4 OH 4 HH 1.40237 120.186 −179.5 107.975 0.960221 70 4 CB 4 CG 4 CD2 4 CE2 1.51034 120.409 177.294 120.705 1.39973 71 4 CE2 4 CG 4 *CD2 4 HD2 1.39973 120.705 −178.803 119.761 1.07995 72 4 CE1 4 CZ 4 CE2 4 CD2 1.40237 119.85 0.53599 119.943 1.39973 73 4 CD2 4 CZ 4 *CE2 4 HE2 1.39973 119.943 179.45 120.375 1.08009 74 4 CG 4 CD2 4 CE2 4 CZ 1.40638 120.705 0.109096 119.943 1.40157 75 4 N 4 CA 4 C 5 N 1.43571 105.423 152.145 115.616 1.34978 76 5 N 4 CA 4 *C 4 O 1.34978 115.616 179.545 121.345 1.23042 77 4 CA 4 C 5 N 5 CA 1.50189 115.616 171.62 123.925 1.43465 78 5 CA 4 C 5 *N 5 HN 1.43465 123.925 −174.775 120.959 0.996966 79 4 C 5 N 5 CA 5 CB 1.34978 123.925 92.1859 114.353 1.53192 80 5 CB 5 N 5 *CA 5 C 1.53192 114.353 123.264 103.547 1.50303 81 5 CB 5 N 5 *CA 5 HA 1.53192 114.353 −122.243 108.645 1.08212 82 5 N 5 CA 5 CB 5 CG2 1.43465 114.353 55.3434 111.533 1.54736 83 5 CG2 5 CA 5 *CB 5 CG1 1.54736 111.533 127.679 111.394 1.55004 84 5 CG2 5 CA 5 *CB 5 HB 1.54736 111.533 −116.263 106.572 1.116 85 5 CA 5 CB 5 CG2 5 HG21 1.53192 111.533 −172.804 110.235 1.1102 86 5 HG21 5 CB 5 *CG2 5 HG22 1.1102 110.235 119.273 111.095 1.10922 87 5 HG21 5 CB 5 *CG2 5 HG23 1.1102 110.235 −119.576 110.822 1.10978 88 5 CA 5 CB 5 CG1 5 CD1 1.53192 111.394 169.263 113.879 1.53193 89 5 CD1 5 CB 5 *CG1 5 HG11 1.53193 113.879 122.02 109.378 1.11145 90 5 CD1 5 CB 5 *CG1 5 HG12 1.53193 113.879 −120.732 108.397 1.11231 91 5 CB 5 CG1 5 CD1 5 HD1 1.55004 113.879 −176.308 110.096 1.11072 92 5 HD1 5 CG1 5 *CD1 5 HD2 1.11072 110.096 119.669 110.341 1.11082 93 5 HD1 5 CG1 5 *CD1 5 HD3 1.11072 110.096 −119.814 110.843 1.11007 94 5 N 5 CA 5 C 6 N 1.43465 103.547 135.689 116.433 1.35318 95 6 N 5 CA 5 *C 5 O 1.35318 116.433 −177.818 121.115 1.23099 96 5 CA 5 C 6 N 6 CA 1.50303 116.433 −179.461 123.347 1.43901 97 6 CA 5 C 6 *N 6 HN 1.43901 123.347 −179.584 121.348 0.99697 98 5 C 6 N 6 CA 6 CB 1.35318 123.347 147.132 111.972 1.5483 99 6 CB 6 N 6 *CA 6 C 1.5483 111.972 118.699 106.414 1.51119 100 6 CB 6 N 6 *CA 6 HA 1.5483 111.972 −120.12 108.82 1.07987 101 6 N 6 CA 6 CB 6 CG 1.43901 111.972 −176.564 113.977 1.50515 102 6 CG 6 CA 6 *CB 6 HB1 1.50515 113.977 120.559 108.672 1.11166 103 6 CG 6 CA 6 *CB 6 HB2 1.50515 113.977 −122.256 109.814 1.11196 104 6 CA 6 CB 6 CG 6 CD2 1.5483 113.977 −107.221 130.139 1.35294 105 6 CD2 6 CB 6 *CG 6 ND1 1.35294 130.139 177.51 122.699 1.36911 106 6 NE2 6 CD2 6 CG 6 CB 1.36882 107.144 177.798 130.139 1.50515 107 6 NE2 6 CG 6 *CD2 6 HD2 1.36882 107.144 −179.227 130.117 1.08377 108 6 CG 6 CD2 6 NE2 6 CE1 1.35294 107.144 −0.0103181 108.36 1.32609 109 6 CE1 6 CD2 6 *NE2 6 HE2 1.32609 108.36 −179.618 125.844 1.00054 110 6 CB 6 CG 6 ND1 6 CE1 1.50515 122.699 −177.981 108.351 1.32626 111 6 CE1 6 CG 6 *ND1 6 HD1 1.32626 108.351 178.888 125.846 1.00123 112 6 CD2 6 NE2 6 CE1 6 ND1 1.36882 108.36 0.027564 109.02 1.32626 113 6 ND1 6 NE2 6 *CE1 6 HE1 1.32626 109.02 179.971 125.496 1.07023 114 6 CG 6 ND1 6 CE1 6 NE2 1.36911 108.351 −0.0339579 109.02 1.32609 115 6 N 6 CA 6 C 7 N 1.43901 106.414 133.108 122.066 1.33418 116 7 N 6 CA 6 *C 6 O 1.33418 122.066 −179.778 117.731 1.23047 117 6 CA 6 C 7 N 7 CD 1.51119 122.066 −9.65365 124.903 1.46364 118 7 CD 6 C 7 *N 7 CA 1.46364 124.903 −171.884 122.724 1.45253 119 6 C 7 N 7 CD 7 CG 1.33418 124.903 174.1 105.121 1.53024 120 7 CG 7 N 7 *CD 7 HD1 1.53024 105.121 118.338 108.494 1.11187 121 7 CG 7 N 7 *CD 7 HD2 1.53024 105.121 −120.135 111.187 1.11004 122 6 C 7 N 7 CA 7 CB 1.33418 122.724 165.431 104.568 1.53695 123 7 CB 7 N 7 *CA 7 C 1.53695 104.568 118.955 109.097 1.50913 124 7 CB 7 N 7 *CA 7 HA 1.53695 104.568 −121.029 110.202 1.08194 125 7 N 7 CA 7 CB 7 CG 1.45253 104.568 25.0499 104.74 1.53274 126 7 CG 7 CA 7 *CB 7 HB1 1.53274 104.74 −115.758 108.594 1.11237 127 7 CG 7 CA 7 *CB 7 HB2 1.53274 104.74 123.04 113.449 1.10755 128 7 N 7 CD 7 CG 7 CB 1.46364 105.121 28.1237 102.974 1.53274 129 7 CB 7 CD 7 *CG 7 HG1 1.53274 102.974 121.498 112.655 1.10758 130 7 CB 7 CD 7 *CG 7 HG2 1.53274 102.974 −116.291 109.372 1.11239 131 7 CA 7 CB 7 CG 7 CD 1.53695 104.74 −32.6465 102.974 1.53024 132 7 N 7 CA 7 C 8 N 1.45253 109.097 139.786 117.1 1.34978 133 8 N 7 CA 7 *C 7 O 1.34978 117.1 −178.478 119.291 1.23067 134 7 CA 7 C 8 N 8 CA 1.50913 117.1 −176.689 122.451 1.43658 135 8 CA 7 C 8 *N 8 HN 1.43658 122.451 178.507 121.773 0.996998 136 7 C 8 N 8 CA 8 CB 1.34978 122.451 89.9685 111.912 1.55784 137 8 CB 8 N 8 *CA 8 C 1.55784 111.912 119.961 105.597 1.5011 138 8 CB 8 N 8 *CA 8 HA 1.55784 111.912 −123.405 109.144 1.08252 139 8 N 8 CA 8 CB 8 CG 1.43658 111.912 −176.81 112.97 1.51086 140 8 CG 8 CA 8 *CB 8 HB1 1.51086 112.97 118.941 109.031 1.11129 141 8 CG 8 CA 8 *CB 8 HB2 1.51086 112.97 −122.534 110.24 1.1111 142 8 CA 8 CB 8 CG 8 CD1 1.55784 112.97 66.5034 120.611 1.40539 143 8 CD1 8 CB 8 *CG 8 CD2 1.40539 120.611 −178.998 120.478 1.4072 144 8 CB 8 CG 8 CD1 8 CE1 1.51086 120.611 −178.907 120.545 1.40053 145 8 CE1 8 CG 8 *CD1 8 HD1 1.40053 120.545 179.791 119.869 1.08054 146 8 CG 8 CD1 8 CE1 8 CZ 1.40539 120.545 −0.00451033 120.039 1.40023 147 8 CZ 8 CD1 8 *CE1 8 HE1 1.40023 120.039 179.83 119.993 1.08001 148 8 CD1 8 CE1 8 CZ 8 CE2 1.40053 120.039 −0.111613 119.949 1.39995 149 8 CE2 8 CE1 8 *CZ 8 HZ 1.39995 119.949 179.95 120.047 1.07977 150 8 CB 8 CG 8 CD2 8 CE2 1.51086 120.478 178.92 120.642 1.40019 151 8 CE2 8 CG 8 *CD2 8 HD2 1.40019 120.642 −179.341 119.829 1.08024 152 8 CE1 8 CZ 8 CE2 8 CD2 1.40023 119.949 0.123335 119.922 1.40019 153 8 CD2 8 CZ 8 *CE2 8 HE2 1.40019 119.922 179.705 120.079 1.07993 154 8 CG 8 CD2 8 CE2 8 CZ 1.4072 120.642 −0.0193345 119.922 1.39995 155 8 N 8 CA 8 C 9 N 1.43658 105.597 143.236 115.826 1.3516 156 9 N 8 CA 8 *C 8 O 1.3516 115.826 179.342 120.94 1.2307 157 8 CA 8 C 9 N 9 CA 1.5011 115.826 170.499 123.977 1.43715 158 9 CA 8 C 9 *N 9 HN 1.43715 123.977 −174.139 120.928 0.996952 159 8 C 9 N 9 CA 9 CB 1.3516 123.977 118.543 113.479 1.54734 160 9 CB 9 N 9 *CA 9 C 1.54734 113.479 118.75 104.671 1.49861 161 9 CB 9 N 9 *CA 9 HA 1.54734 113.479 −124.111 110.422 1.08183 162 9 N 9 CA 9 CB 9 CG 1.43715 113.479 177.199 113.8 1.50625 163 9 CG 9 CA 9 *CB 9 HB1 1.50625 113.8 120.99 108.766 1.11205 164 9 CG 9 CA 9 *CB 9 HB2 1.50625 113.8 −121.739 109.568 1.11199 165 9 CA 9 CB 9 CG 9 CD2 1.54734 113.8 −112.438 130.016 1.35431 166 9 CD2 9 CB 9 *CG 9 ND1 1.35431 130.016 176.612 122.815 1.36898 167 9 NE2 9 CD2 9 CG 9 CB 1.36906 107.106 177.205 130.016 1.50625 168 9 NE2 9 CG 9 *CD2 9 HD2 1.36906 107.106 −179.46 130.116 1.08285 169 9 CG 9 CD2 9 NE2 9 CE1 1.35431 107.106 −0.0763064 108.392 1.32551 170 9 CE1 9 CD2 9 *NE2 9 HE2 1.32551 108.392 −179.729 125.778 1.00133 171 9 CB 9 CG 9 ND1 9 CE1 1.50625 122.815 −177.513 108.365 1.32659 172 9 CE1 9 CG 9 *ND1 9 HD1 1.32659 108.365 178.824 125.804 1.00073 173 9 CD2 9 NE2 9 CE1 9 ND1 1.36906 108.392 −0.065808 109.035 1.32659 174 9 ND1 9 NE2 9 *CE1 9 HE1 1.32659 109.035 −179.774 125.469 1.07077 175 9 CG 9 ND1 9 CE1 9 NE2 1.36898 108.365 0.181656 109.035 1.32551 176 9 N 9 CA 9 C 10 N 1.43715 104.671 134.529 116.388 1.35182 177 10 N 9 CA 9 *C 9 O 1.35182 116.388 −179.594 120.657 1.23024 178 9 CA 9 C 10 N 10 CA 1.49861 116.388 179.245 123.407 1.44123 179 10 CA 9 C 10 *N 10 HN 1.44123 123.407 −179.309 121.291 0.997408 180 9 C 10 N 10 CA 10 CB 1.35182 123.407 146.897 111.683 1.55057 181 10 CB 10 N 10 *CA 10 C 1.55057 111.683 121.658 106.26 1.53598 182 10 CB 10 N 10 *CA 10 HA 1.55057 111.683 −119.853 108.94 1.08178 183 10 N 10 CA 10 CB 10 CG 1.44123 111.683 −161.882 115.978 1.55118 184 10 CG 10 CA 10 *CB 10 HB1 1.55118 115.978 118.31 106.391 1.11438 185 10 CG 10 CA 10 *CB 10 HB2 1.55118 115.978 −126.021 110.581 1.11009 186 10 CA 10 CB 10 CG 10 CD1 1.55057 115.978 164.138 110.337 1.54138 187 10 CD1 10 CB 10 *CG 10 CD2 1.54138 110.337 125.024 114.35 1.54198 188 10 CD1 10 CB 10 *CG 10 HG 1.54138 110.337 −115.943 107.21 1.11444 189 10 CB 10 CG 10 CD1 10 HD11 1.55118 110.337 −176.558 110.296 1.11023 190 10 HD11 10 CG 10 *CD1 10 HD12 1.11023 110.296 119.913 110.357 1.1105 191 10 HD11 10 CG 10 *CD1 10 HD13 1.11023 110.296 −120.002 110.284 1.11049 192 10 CB 10 CG 10 CD2 10 HD21 1.55118 114.35 −176.316 109.986 1.11044 193 10 HD21 10 CG 10 *CD2 10 HD22 1.11044 109.986 119.691 110.303 1.11063 194 10 HD21 10 CG 10 *CD2 10 HD23 1.11044 109.986 −119.439 111.037 1.10853 195 10 N 10 CA 10 C 10 OE1 1.44123 106.26 −65.2432 118.282 1.25984 196 10 OE1 10 CA 10 *C 10 OE2 1.25984 118.282 179.375 117.928 1.25963

Structural Restraint Files for AngiotensinI

1) 2D-NOESY restraints file: [for the sake of brevity, only the header is given here. The data for all 343 NOE and 383 noNOE restraints is given implicitly in the χ² _(restraint) values file below]

remark 2D NOESY remark TRANS angiotensin1 configuration: field 600 solvent h2o temp 278 visc 1.54 ident 2D-NOESY mix_time 700 ms endsection 2) Scalar coupling restraints files:

remark conformation-dependent scalar couplings for angtensinI, 5 deg C. remark TRANS angiotensinI configuration: field 600 solvent h2o temp 278 visc 1.54 ident J5DEGC endsection data: coup 1 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 8.06 0.4 0 coup 2 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.64 0.4 0 coup 3 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.62 0.4 0 coup 4 6 HA 6 CA 6 N 6 HN 7.9 −1.05 0.65 0 6.37 0.4 0 coup 5 8 HA 8 CA 8 N 8 HN 7.9 −1.05 0.65 0 6.55 0.4 0 coup 6 9 HA 9 CA 9 N 9 HN 7.9 −1.05 0.65 0 7.41 0.4 0 coup 7 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.25 0.4 0 coup 8 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 7.94 0.4 0 coup 9 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.47 0.4 0 coup 10 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.24 0.4 0 coup 11 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 7.84 0.4 0 coup 12 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.43 0.4 0 coup 13 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.22 0.4 0 coup 14 1 HA 1 CA 1 CB 1 HB1 7.23 −1.37 2.22 0 5.32 0.5 0 coup 15 1 HA 1 CA 1 CB 1 HB2 7.23 −1.37 2.22 0 8.26 0.5 0 coup 16 1 HA 1 CA 1 CB 1 HB1 7.23 −1.37 2.22 0 4.99 0.5 0 coup 17 1 HA 1 CA 1 CB 1 HB2 7.23 −1.37 2.22 0 8.66 0.5 0 coup 18 2 HA 2 CA 2 CB 2 HB1 7.23 −1.37 2.22 0 6.85 0.5 0 coup 19 2 HA 2 CA 2 CB 2 HB2 7.23 −1.37 2.22 0 6.85 0.5 0 coup 20 3 HA 3 CA 3 CB 3 HB 7.23 −1.37 2.22 0 8.29 0.5 0 coup 21 5 HA 5 CA 5 CB 5 HB 7.23 −1.37 2.22 0 9.23 0.5 0 coup 22 6 HA 6 CA 6 CB 6 HB1 7.23 −1.37 2.22 0 19.51 1.5 0 ovlp 22 6 HA 6 CA 6 CB 6 HB2 7.23 −1.37 2.22 0 19.51 1.5 0 ovlp 22 6 HA 6 CA 6 N 6 HN 7.9 −1.05 0.65 0 19.51 1.5 0 coup 23 6 HA 6 CA 6 CB 6 HB1 7.23 −1.37 2.22 0 4.73 0.5 0 coup 23 6 HA 6 CA 6 CB 6 HB2 7.23 −1.37 2.22 0 8.13 0.5 0 coup 24 9 HA 9 CA 9 CB 9 HB1 7.23 −1.37 2.22 0 19.2 1.5 0 ovlp 24 9 HA 9 CA 9 CB 9 HB2 7.23 −1.37 2.22 0 19.2 1.5 0 ovlp 24 9 HA 9 CA 9 N 9 HN 7.9 −1.05 0.65 0 19.2 1.5 0 coup 25 10 HA 10 CA 10 CB 10 HB1 7.23 −1.37 2.22 0 20.9 1.5 0 ovlp 25 10 HA 10 CA 10 CB 10 HB2 7.23 −1.37 2.22 0 20.9 1.5 0 ovlp 25 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 20.9 1.5 0 endsection remark conformation-dependent scalar couplings for angtensinI, 15 deg C. remark TRANS angiotensinI configuration: field 600 solvent h2o temp 288 visc 1.54 ident J15DEGC endsection data: coup 1 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 8.12 0.4 0 coup 2 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.73 0.4 0 coup 3 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.58 0.4 0 coup 4 6 HA 6 CA 6 N 6 HN 7.9 −1.05 0.65 0 6.43 0.4 0 coup 5 8 HA 8 CA 8 N 8 HN 7.9 −1.05 0.65 0 6.63 0.4 0 coup 6 9 HA 9 CA 9 N 9 HN 7.9 −1.05 0.65 0 7.19 0.4 0 coup 7 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.36 0.4 0 coup 8 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 7.94 0.3 0 coup 9 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.52 0.3 0 endsection remark conformation-dependent scalar couplings for angtensinI, 25° C. remark TRANS angiotensinI configuration: field 600 solvent h2o temp 298 visc 0.88 ident JCOUP endsection data: coup 1 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 8.21 0.4 0 coup 2 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.96 0.4 0 coup 3 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.54 0.4 0 coup 4 6 HA 6 CA 6 N 6 HN 7.9 −1.05 0.65 0 6.04 0.4 0 coup 5 8 HA 8 CA 8 N 8 HN 7.9 −1.05 0.65 0 6.73 0.4 0 coup 7 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.61 0.4 0 coup 8 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 7.90 0.4 0 coup 9 4 HA 4 CA 4 N 4 HN 7.9 −1.05 0.65 0 7.45 0.4 0 coup 10 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.31 0.4 0 coup 11 1 HA 1 CA 1 CB 1 HB1 7.23 −1.37 2.22 0 12.85 1.0 0 ovlp 11 1 HA 1 CA 1 CB 1 HB2 7.23 −1.37 2.22 0 12.85 1.0 0 coup 12 1 HA 1 CA 1 CB 1 HB1 7.23 −1.37 2.22 0 4.46 0.5 0 coup 13 1 HA 1 CA 1 CB 1 HB2 7.23 −1.37 2.22 0 8.38 0.5 0 coup 14 2 HA 2 CA 2 CB 2 HB1 7.23 −1.37 2.22 0 6.91 0.5 0 coup 15 2 HA 2 CA 2 CB 2 HB2 7.23 −1.37 2.22 0 6.91 0.5 0 coup 16 3 HA 3 CA 3 CB 3 HB 7.23 −1.37 2.22 0 7.79 0.5 0 coup 17 5 HA 5 CA 5 CB 5 HB 7.23 −1.37 2.22 0 7.89 0.5 0 coup 18 6 HA 6 CA 6 CB 6 HB1 7.23 −1.37 2.22 0 4.93 0.5 0 coup 19 6 HA 6 CA 6 CB 6 HB2 7.23 −1.37 2.22 0 8.34 0.5 0 coup 21 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 7.97 0.5 0 coup 23 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.34 0.5 0 coup 24 8 HA 8 CA 8 N 8 HN 7.9 −1.05 0.65 0 6.49 0.5 0 coup 25 10 HA 10 CA 10 N 10 HN 7.9 −1.05 0.65 0 7.10 0.5 0 coup 30 3 HA 3 CA 3 N 3 HN 7.9 −1.05 0.65 0 8.04 0.4 0 coup 31 5 HA 5 CA 5 N 5 HN 7.9 −1.05 0.65 0 8.33 0.4 0 coup 32 5 HG11 5 CG1 5 CB 5 HB 12.0 −1.0 2.0 0 5.8 1.0 0 coup 33 5 HG12 5 CG1 5 CB 5 HB 12.0 −1.0 2.0 0 8.0 0.6 0 endsection 3) Dihedral restraints file:

remark Angiotensin1, dihedral angle restraints remark given twice the error value from TALOS configuration: field 600 solvent h2o temp 298 visc 0.88 ident TDIHEDRALS endsection data: remark dihedral_no dihedral_atom_identifiers (x8) angle error code remark phi dihe 1 1 C 2 N 2 CA 2 C −85 26 0 dihe 2 2 C 3 N 3 CA 3 C −100 34 0 dihe 3 3 C 4 N 4 CA 4 C −120 60 0 dihe 4 4 C 5 N 5 CA 5 C −100 24 0 dihe 5 5 C 6 N 6 CA 6 C −93 46 0 dihe 6 6 C 7 N 7 CA 7 C −71 16 0 dihe 7 7 C 8 N 8 CA 8 C −113 52 0 dihe 8 8 C 9 N 9 CA 9 C −103 42 0 remark psi dihe 9 2 N 2 CA 2 C 3 N 138 36 0 dihe 10 3 N 3 CA 3 C 4 N 130 36 0 dihe 11 4 N 4 CA 4 C 5 N 120 14 0 dihe 12 5 N 5 CA 5 C 6 N 121 18 0 dihe 13 6 N 6 CA 6 C 7 N 122 16 0 dihe 14 7 N 7 CA 7 C 8 N 146 28 0 dihe 15 8 N 8 CA 8 C 9 N 129 36 0 remark omega dihe 17 3 CA 3 C 4 N 4 CA 180 20 0 endsection 4) Hydrogen bond restraints file:

remark hydrogen bond restraints file for AngiotensinI configuration: solvent h2o ident HBOND endsection data: remark atomsx3 d1 range d2 range ang percent perc_error start code 2 3 N 3 HN 1 O 2.9 0.4 2.0 0.5 110 0 10 0.0 0 hcomb 2 3 N 3 HN 1 OD1 hcomb 2 3 N 3 HN 1 OD2 hcomb 2 3 N 3 HN 2 O hcomb 2 3 N 3 HN 4 O hcomb 2 3 N 3 HN 4 OH hcomb 2 3 N 3 HN 5 O hcomb 2 3 N 3 HN 6 O hcomb 2 3 N 3 HN 6 ND1 hcomb 2 3 N 3 HN 6 NE2 hcomb 2 3 N 3 HN 7 O hcomb 2 3 N 3 HN 8 O hcomb 2 3 N 3 HN 9 O hcomb 2 3 N 3 HN 9 ND1 hcomb 2 3 N 3 HN 9 NE2 hcomb 2 3 N 3 HN 10 OE1 hcomb 2 3 N 3 HN 10 OE1 hbond 3 4 N 4 HN 1 O 2.9 0.4 2.0 0.5 110 0 10 0.0 0 hcomb 3 4 N 4 HN 1 OD1 hcomb 3 4 N 4 HN 1 OD2 hcomb 3 4 N 4 HN 2 O hcomb 3 4 N 4 HN 3 O hcomb 3 4 N 4 HN 4 OH hcomb 3 4 N 4 HN 5 O hcomb 3 4 N 4 HN 6 O hcomb 3 4 N 4 HN 6 ND1 hcomb 3 4 N 4 HN 6 NE2 hcomb 3 4 N 4 HN 7 O hcomb 3 4 N 4 HN 8 O hcomb 3 4 N 4 HN 9 O hcomb 3 4 N 4 HN 9 ND1 hcomb 3 4 N 4 HN 9 NE2 hcomb 3 4 N 4 HN 10 OE1 hcomb 3 4 N 4 HN 10 OE1 hbond 4 6 N 6 HN 1 O 2.9 0.4 2.0 0.5 110 0 10 0.0 0 hcomb 4 6 N 6 HN 1 OD1 hcomb 4 6 N 6 HN 1 OD2 hcomb 4 6 N 6 HN 2 O hcomb 4 6 N 6 HN 3 O hcomb 4 6 N 6 HN 4 O hcomb 4 6 N 6 HN 4 OH hcomb 4 6 N 6 HN 5 O hcomb 4 6 N 6 HN 6 ND1 hcomb 4 6 N 6 HN 6 NE2 hcomb 4 6 N 6 HN 7 O hcomb 4 6 N 6 HN 8 O hcomb 4 6 N 6 HN 9 O hcomb 4 6 N 6 HN 9 ND1 hcomb 4 6 N 6 HN 9 NE2 hcomb 4 6 N 6 HN 10 OE1 hcomb 4 6 N 6 HN 10 OE1 hbond 5 8 N 8 HN 1 O 2.9 0.4 2.0 0.5 110 0 10 0.0 0 hcomb 5 8 N 8 HN 1 OD1 hcomb 5 8 N 8 HN 1 OD2 hcomb 5 8 N 8 HN 2 O hcomb 5 8 N 8 HN 3 O hcomb 5 8 N 8 HN 4 O hcomb 5 8 N 8 HN 4 OH hcomb 5 8 N 8 HN 5 O hcomb 5 8 N 8 HN 6 O hcomb 5 8 N 8 HN 6 ND1 hcomb 5 8 N 8 HN 6 NE2 hcomb 5 8 N 8 HN 7 O hcomb 5 8 N 8 HN 9 O hcomb 5 8 N 8 HN 9 ND1 hcomb 5 8 N 8 HN 9 NE2 hcomb 5 8 N 8 HN 10 OE1 hcomb 5 8 N 8 HN 10 OE1 hbond 6 10 N 10 HN 1 O 2.9 0.4 2.0 0.5 110 0 20 0.0 0 hcomb 6 10 N 10 HN 1 OD1 hcomb 6 10 N 10 HN 1 OD2 hcomb 6 10 N 10 HN 2 O hcomb 6 10 N 10 HN 3 O hcomb 6 10 N 10 HN 4 O hcomb 6 10 N 10 HN 4 OH hcomb 6 10 N 10 HN 5 O hcomb 6 10 N 10 HN 6 O hcomb 6 10 N 10 HN 6 ND1 hcomb 6 10 N 10 HN 6 NE2 hcomb 6 10 N 10 HN 7 O hcomb 6 10 N 10 HN 8 O hcomb 6 10 N 10 HN 9 O hcomb 6 10 N 10 HN 9 ND1 hcomb 6 10 N 10 HN 9 NE2 endsection

χ² _(restraint) Values for the Best Optimised Dynamic Structure of AngiotensinI

5 8 N 8 HN 1 O 0.00 10.00 0.00 0.00 0.0 0 16 HBOND 17 3D 3 CA 3D 4 CA 180.00 20.00 180.00 0.00 0.0 0 0 TDIHEDRALS 1147 D1 1 HB1 L10 10 HD11 0.00 94.00 0.00 0.00 0.0 0 2 2D-NOESY 1148 D1 1 HB1 L10 10 HD21 0.00 77.00 0.00 0.00 0.0 0 2 2D-NOESY 540 H9 9 HA D1 1 HB1 0.00 99.00 0.01 0.00 0.0 5 0 2D-NOESY 541 H9 9 HD2 D1 1 HB1 0.00 76.00 0.00 0.00 0.0 0 0 2D-NOESY 521 H9 9 HB2 D1 1 HA 0.00 81.00 0.01 0.00 0.0 5 0 2D-NOESY 567 H9 9 HD2 D1 1 HB2 0.00 53.00 0.00 0.00 0.0 0 0 2D-NOESY 545 L10 10 HN D1 1 HB1 0.00 18.00 0.00 0.00 0.0 5 0 2D-NOESY 1057 D1 1 HB2 H9 9 HD2 0.00 40.00 0.00 0.00 0.0 0 0 2D-NOESY 570 L10 10 HA D1 1 HB2 0.00 22.00 0.00 0.00 0.0 5 0 2D-NOESY 1056 D1 1 HB1 H9 9 HD2 0.00 33.00 0.00 0.00 0.0 0 0 2D-NOESY 1050 R2 2 HB1 H9 9 HA 0.00 66.00 0.01 0.00 0.0 5 1 2D-NOESY 566 H9 9 HA D1 1 HB2 0.00 29.00 0.01 0.00 0.0 5 0 2D-NOESY 1052 R2 2 HB1 H9 9 HB2 0.00 31.00 0.01 0.00 0.0 5 1 2D-NOESY 522 H9 9 HD2 D1 1 HA 0.00 48.00 0.01 0.00 0.0 0 0 2D-NOESY 641 L10 10 HA R2 2 HG1 0.00 21.00 0.01 0.00 0.0 2 1 2D-NOESY 1108 R2 2 HA H9 9 HN 0.00 7.50 0.00 0.00 0.0 1 0 2D-NOESY 721 L10 10 HB1 V3 3 HN 0.00 2.70 0.00 0.00 0.0 1 2 2D-NOESY 1128 D1 1 HB2 L10 10 HB1 0.00 17.00 0.00 0.00 0.0 5 2 2D-NOESY 717 H9 9 HA V3 3 HN 0.00 4.10 0.00 0.00 0.0 1 0 2D-NOESY 830 L10 10 HA I5 5 HG12 0.00 420.00 0.11 0.00 0.0 5 0 2D-NOESY 523 L10 10 HB1 D1 1 HA 0.00 36.00 0.01 0.00 0.0 5 2 2D-NOESY 543 L10 10 HA D1 1 HB1 0.00 11.00 0.00 0.00 0.0 5 0 2D-NOESY 568 H9 9 HE1 D1 1 HB2 0.00 21.00 0.01 0.00 0.0 0 0 2D-NOESY 1129 R2 2 HA L10 10 HB1 0.00 25.00 0.01 0.00 0.0 0 2 2D-NOESY 1119 R2 2 HG1 L10 10 HA 0.00 14.00 0.01 0.00 0.0 2 1 2D-NOESY 1049 D1 1 HA H9 9 HA 0.00 31.00 0.01 0.00 0.0 5 0 2D-NOESY 544 L10 10 HB1 D1 1 HB1 0.00 11.00 0.00 0.00 0.0 5 2 2D-NOESY 542 H9 9 HE1 D1 1 HB1 0.00 17.00 0.01 0.00 0.0 0 0 2D-NOESY 572 L10 10 HN D1 1 HB2 0.00 4.40 0.00 0.00 0.0 5 0 2D-NOESY 642 L10 10 HN R2 2 HG1 0.00 9.30 0.00 0.00 0.0 2 1 2D-NOESY 1105 D1 1 HA H9 9 HN 0.00 3.70 0.00 0.00 0.0 1 0 2D-NOESY 1015 D1 1 HA F8 8 HN 0.00 21.00 0.01 0.00 0.0 1 0 2D-NOESY 686 L10 10 HB1 V3 3 HG21 0.00 81.00 0.04 0.00 0.0 5 8 2D-NOESY 561 F8 8 HA D1 1 HB2 0.00 29.00 0.01 0.00 0.0 5 0 2D-NOESY 1055 D1 1 HA H9 9 HD2 0.00 22.00 0.01 0.00 0.0 0 0 2D-NOESY 569 H9 9 HN D1 1 HB2 0.00 14.00 0.01 0.00 0.0 5 0 2D-NOESY 718 H9 9 HB1 V3 3 HN 0.00 2.50 0.00 0.00 0.0 1 1 2D-NOESY 639 H9 9 HE1 R2 2 HG1 0.00 52.00 0.02 0.00 0.0 0 1 2D-NOESY 1109 R2 2 HG1 H9 9 HN 0.00 3.80 0.00 0.00 0.0 1 1 2D-NOESY 571 L10 10 HB1 D1 1 HB2 0.00 8.80 0.00 0.00 0.0 5 2 2D-NOESY 640 H9 9 HN R2 2 HG1 0.00 34.00 0.02 0.00 0.0 2 1 2D-NOESY 713 F8 8 HD1 V3 3 HN 0.00 16.00 0.01 0.00 0.0 0 1 2D-NOESY 1120 V3 3 HN L10 10 HA 0.00 15.00 0.01 0.00 0.0 5 0 2D-NOESY 519 F8 8 HB1 D1 1 HA 0.00 91.00 0.05 0.00 0.0 5 1 2D-NOESY 536 F8 8 HD1 D1 1 HB1 0.00 76.00 0.04 0.00 0.0 0 1 2D-NOESY 537 F8 8 HE2 D1 1 HB1 0.00 60.00 0.03 0.00 0.0 0 0 2D-NOESY 1059 R2 2 HG1 H9 9 HD2 0.00 21.00 0.01 0.00 0.0 0 1 2D-NOESY 1130 V3 3 HB L10 10 HB1 0.00 23.00 0.02 0.00 0.0 0 2 2D-NOESY 562 F8 8 HD1 D1 1 HB2 0.00 63.00 0.04 0.00 0.0 0 1 2D-NOESY 716 F8 8 HZ V3 3 HN 0.00 9.80 0.01 0.00 0.0 0 0 2D-NOESY 637 H9 9 HA R2 2 HG1 0.00 19.00 0.01 0.00 0.0 2 1 2D-NOESY 708 P7 7 HB2 V3 3 HN 0.00 11.00 0.01 0.00 0.0 1 0 2D-NOESY 812 L10 10 HA I5 5 HG11 0.00 140.00 0.10 0.00 0.0 5 0 2D-NOESY 539 F8 8 HZ D1 1 HB1 0.00 60.00 0.04 0.00 0.0 0 0 2D-NOESY 711 F8 8 HA V3 3 HN 0.00 4.10 0.00 0.00 0.0 1 0 2D-NOESY 1131 V3 3 HN L10 10 HB1 0.00 15.00 0.01 0.00 0.0 0 2 2D-NOESY 1016 D1 1 HB1 F8 8 HN 0.00 5.30 0.00 0.00 0.0 1 0 2D-NOESY 988 D1 1 HB1 F8 8 HD1 0.00 48.00 0.04 0.00 0.0 0 1 2D-NOESY 1017 D1 1 HB2 F8 8 HN 0.00 4.30 0.00 0.00 0.0 1 0 2D-NOESY 538 F8 8 HN D1 1 HB1 0.00 19.00 0.02 0.00 0.0 5 0 2D-NOESY 1062 V3 3 HN H9 9 HD2 0.00 19.00 0.02 0.00 0.0 0 0 2D-NOESY 1136 I5 5 HG12 L10 10 HB1 0.00 85.00 0.10 0.00 0.0 0 2 2D-NOESY 565 F8 8 HZ D1 1 HB2 0.00 42.00 0.04 0.00 0.0 0 0 2D-NOESY 813 L10 10 HB1 I5 5 HG11 0.00 78.00 0.09 0.00 0.0 5 2 2D-NOESY 563 F8 8 HE1 D1 1 HB2 0.00 60.00 0.06 0.00 0.0 0 1 2D-NOESY 564 F8 8 HN D1 1 HB2 0.00 15.00 0.02 0.00 0.0 5 0 2D-NOESY 973 D1 1 HB2 F8 8 HA 0.00 10.00 0.01 0.00 0.0 5 0 2D-NOESY 1001 D1 1 HB1 F8 8 HE1 0.00 52.00 0.07 0.00 0.0 0 1 2D-NOESY 968 D1 1 HB2 P7 7 HD2 0.00 42.00 0.06 0.00 0.0 5 0 2D-NOESY 714 F8 8 HE1 V3 3 HN 0.00 9.80 0.01 0.00 0.0 0 1 2D-NOESY 956 D1 1 HB1 P7 7 HD1 0.00 53.00 0.07 0.00 0.0 5 0 2D-NOESY 638 H9 9 HD2 R2 2 HG1 0.00 9.60 0.01 0.00 0.0 0 1 2D-NOESY 560 P7 7 HD2 D1 1 HB2 0.00 40.00 0.06 0.00 0.0 5 0 2D-NOESY 1058 R2 2 HB1 H9 9 HD2 0.00 8.00 0.01 0.00 0.0 0 1 2D-NOESY 923 D1 1 HB1 P7 7 HB1 0.00 21.00 0.03 0.00 0.0 5 0 2D-NOESY 648 L10 10 HB1 V3 3 HA 0.00 8.60 0.02 0.00 0.0 5 2 2D-NOESY 687 L10 10 HN V3 3 HG21 0.00 16.00 0.03 0.00 0.0 5 2 2D-NOESY 679 F8 8 HB1 V3 3 HG21 0.00 36.00 0.06 0.00 0.0 5 0 2D-NOESY 712 F8 8 HB1 V3 3 HG21 0.00 2.70 0.00 0.00 0.0 1 1 2D-NOESY 632 F8 8 HB1 V3 3 HN 0.00 23.00 0.04 0.00 0.0 2 3 2D-NOESY 985 R2 2 HB1 F8 8 HB1 0.00 22.00 0.04 0.00 0.0 5 3 2D-NOESY 974 R2 2 HB1 F8 8 HA 0.00 16.00 0.03 0.00 0.0 5 1 2D-NOESY 978 V3 3 HN F8 8 HA 0.00 32.00 0.07 0.00 0.0 5 0 2D-NOESY 990 R2 2 HG1 F8 8 HD1 0.00 32.00 0.07 0.00 0.0 0 3 2D-NOESY 636 F8 8 HZ R2 2 HG1 0.00 19.00 0.04 0.00 0.0 0 1 2D-NOESY 520 F8 8 HE1 D1 1 HA 0.00 48.00 0.11 0.00 0.0 0 1 2D-NOESY 986 R2 2 HG1 F8 8 HB1 0.00 18.00 0.04 0.00 0.0 2 3 2D-NOESY 513 H6 6 HB1 D1 1 HA 0.00 81.00 0.20 0.00 0.0 5 0 2D-NOESY 1000 D1 1 HA F8 8 HE1 0.00 47.00 0.11 0.00 0.0 0 1 2D-NOESY 1110 V3 3 HG11 H9 9 HN 0.00 4.10 0.01 0.00 0.0 0 2 2D-NOESY 1135 Y4 4 HN L10 10 HB1 0.00 8.60 0.02 0.00 0.0 5 2 2D-NOESY 987 D1 1 HA F8 8 HD1 0.00 31.00 0.08 0.00 0.0 0 1 2D-NOESY 957 D1 1 HB2 P7 7 HD1 0.00 30.00 0.07 0.00 0.0 5 0 2D-NOESY 831 L10 10 HB1 I5 5 HG12 0.00 31.00 0.10 0.00 0.0 5 2 2D-NOESY 684 H9 9 HB2 V3 3 HG21 0.00 16.00 0.05 0.00 0.0 5 2 2D-NOESY 535 P7 7 HG1 D1 1 HB1 0.00 23.00 0.07 0.00 0.0 5 1 2D-NOESY 1063 Y4 4 HN H9 9 HD2 0.00 23.00 0.06 0.00 0.0 0 0 2D-NOESY 683 H9 9 HB1 V3 3 HG21 0.00 19.00 0.05 0.00 0.0 5 2 2D-NOESY 922 D1 1 HB2 P7 7 HA 0.00 22.00 0.07 0.00 0.0 5 0 2D-NOESY 1018 R2 2 HG1 F8 8 HN 0.00 4.60 0.02 0.00 0.0 1 1 2D-NOESY 627 P7 7 HB1 R2 2 HG1 0.00 40.00 0.16 0.00 0.0 2 1 2D-NOESY 516 P7 7 HB1 D1 1 HA 0.00 16.00 0.07 0.00 0.0 5 0 2D-NOESY 532 H6 6 HA D1 1 HB1 0.00 25.00 0.11 0.00 0.0 5 0 2D-NOESY 1060 V3 3 HA H9 9 HD2 0.00 9.10 0.03 0.00 0.0 0 0 2D-NOESY 705 H6 6 HE1 V3 3 HN 0.00 21.00 0.07 0.00 0.0 1 0 2D-NOESY 619 I5 5 HG12 R2 2 HG1 0.00 270.00 1.30 0.00 0.0 2 1 2D-NOESY 873 D1 1 HB1 H6 6 HA 0.00 22.00 0.11 0.00 0.0 5 0 2D-NOESY 631 F8 8 HA R2 2 HG1 0.00 6.90 0.04 0.00 0.0 2 1 2D-NOESY 1061 V3 3 HG21 H9 9 HD2 0.00 21.00 0.09 0.00 0.0 0 2 2D-NOESY 533 H6 6 HE1 D1 1 HB1 0.00 23.00 0.11 0.00 0.0 4 0 2D-NOESY 855 L10 10 HN I5 5 HD1 0.00 38.00 0.20 0.00 0.0 5 2 2D-NOESY 926 V3 3 HG11 P7 7 HB1 0.00 180.00 0.93 0.00 0.0 5 2 2D-NOESY 1121 Y4 4 HD1 L10 10 HA 0.00 24.00 0.11 0.00 0.0 5 1 2D-NOESY 647 F8 8 HZ V3 3 HA 0.00 23.00 0.13 0.00 0.0 0 0 2D-NOESY 685 H9 9 HD2 V3 3 HG21 0.00 19.00 0.09 0.00 0.0 0 2 2D-NOESY 810 H9 9 HB1 I5 5 HG11 0.00 14.00 0.08 0.00 0.0 5 0 2D-NOESY 815 L10 10 HN I5 5 HG11 0.00 8.30 0.05 0.00 0.0 5 0 2D-NOESY 557 H6 6 HD2 D1 1 HB2 0.00 53.00 0.27 0.00 0.0 0 0 2D-NOESY 727 L10 10 HB1 Y4 4 HB1 0.00 14.00 0.09 0.00 0.0 5 5 2D-NOESY 556 H6 6 HA D1 1 HB2 0.00 16.00 0.10 0.00 0.0 5 0 2D-NOESY 1003 V3 3 HA F8 8 HE1 0.00 70.00 0.35 0.00 0.0 0 1 2D-NOESY 1132 Y4 4 HB1 L10 10 HB1 0.00 14.00 0.09 0.00 0.0 5 5 2D-NOESY 1002 R2 2 HG1 F8 8 HE1 0.00 21.00 0.11 0.00 0.0 0 3 2D-NOESY 635 F8 8 HN R2 2 HG1 0.00 11.00 0.07 0.00 0.0 2 1 2D-NOESY 927 V3 3 HG21 P7 7 HB1 0.00 180.00 1.20 0.00 0.0 5 2 2D-NOESY 633 F8 8 HD1 R2 2 HG1 0.00 10.00 0.07 0.00 0.0 0 3 2D-NOESY 1123 I5 5 HG11 L10 10 HA 0.00 15.00 0.10 0.00 0.0 5 0 2D-NOESY 1122 I5 5 HB L10 10 HA 0.00 18.00 0.13 0.00 0.0 5 0 2D-NOESY 833 L10 10 HN I5 5 HG12 0.00 7.50 0.06 0.00 0.0 5 0 2D-NOESY 872 D1 1 HA H6 6 HA 0.00 42.00 0.30 0.00 0.0 5 0 2D-NOESY 518 P7 7 HG1 D1 1 HA 0.00 23.00 0.17 0.00 0.0 5 1 2D-NOESY 558 H6 6 HE1 D1 1 HB2 0.00 15.00 0.10 0.00 0.0 4 0 2D-NOESY 634 F8 8 HE1 R2 2 HG1 0.00 19.00 0.11 0.00 0.0 0 3 2D-NOESY 994 V3 3 HN F8 8 HD1 0.00 22.00 0.18 0.00 0.0 0 1 2D-NOESY 975 R2 2 HG1 F8 8 HA 0.00 4.30 0.04 0.00 0.0 2 1 2D-NOESY 844 L10 10 HN I5 5 HG21 0.00 30.00 0.25 0.00 0.0 5 2 2D-NOESY 991 V3 3 HA F8 8 HD1 0.00 22.00 0.19 0.00 0.0 0 1 2D-NOESY 739 L10 10 HA Y4 4 HE1 0.00 25.00 0.21 0.00 0.0 5 1 2D-NOESY 897 D1 1 HB2 H6 6 HD2 0.00 38.00 0.27 0.00 0.0 4 0 2D-NOESY 989 R2 2 HB1 F8 8 HD1 0.00 7.00 0.07 0.00 0.0 0 3 2D-NOESY 827 F8 8 HA I5 5 HG12 0.00 110.00 1.10 0.00 0.0 5 0 2D-NOESY 1053 I5 5 HG12 H9 9 HB1 0.00 16.00 0.17 0.00 0.0 5 1 2D-NOESY 1066 I5 5 HG11 H9 9 HD2 0.00 21.00 0.21 0.00 0.0 0 0 2D-NOESY 829 H9 9 HB1 I5 5 HG12 0.00 15.00 0.17 0.00 0.0 5 1 2D-NOESY 976 V3 3 HG11 F8 8 HA 0.00 19.00 0.22 0.00 0.0 5 2 2D-NOESY 732 L10 10 HB1 Y4 4 HD1 0.00 20.00 0.20 0.00 0.0 5 5 2D-NOESY 816 D1 1 HB1 I5 5 HG12 0.00 75.00 0.79 0.00 0.0 5 0 2D-NOESY 821 V3 3 HG11 I5 5 HG12 0.00 2900.00 33.00 0.00 0.0 5 2 2D-NOESY 1125 H6 6 HN L10 10 HA 0.00 17.00 0.20 0.00 0.0 5 0 2D-NOESY 3 4 N 4 HN 1 O 0.00 10.00 0.03 0.00 0.0 0 16 HBOND 707 P7 7 HB1 V3 3 HN 0.00 0.95 0.01 0.00 0.0 1 0 2D-NOESY 1124 I5 5 HG12 L10 10 HA 0.00 8.60 0.11 0.00 0.0 5 0 2D-NOESY 835 D1 1 HB1 I5 5 HG21 0.00 86.00 0.99 0.00 0.0 5 2 2D-NOESY 924 R2 2 HD1 P7 7 HB1 0.00 47.00 0.34 0.00 0.0 2 1 2D-NOESY 798 R2 2 HG1 I5 5 HG11 0.00 110.00 1.50 0.00 0.0 2 1 2D-NOESY 667 P7 7 HB2 V3 3 HG11 0.00 48.00 0.60 0.00 0.0 5 2 2D-NOESY 1004 V3 3 HG21 F8 8 HE1 0.00 120.00 1.50 0.00 0.0 0 5 2D-NOESY 822 V3 3 HG21 I5 5 HG12 0.00 2900.00 39.00 0.00 0.0 5 2 2D-NOESY 517 P7 7 HD2 D1 1 HA 0.00 12.00 0.17 0.00 0.0 5 0 2D-NOESY 887 L10 10 HA H6 6 HA 0.00 22.00 0.32 0.00 0.0 5 0 2D-NOESY 874 D1 1 HB2 H6 6 HA 0.00 6.70 0.10 0.00 0.0 5 0 2D-NOESY 527 Y4 4 HA D1 1 HB1 0.00 84.00 1.20 0.00 0.0 5 0 2D-NOESY 925 R2 2 HG1 P7 7 HB1 0.00 11.00 0.16 0.00 0.0 2 1 2D-NOESY 702 H6 6 HB1 V3 3 HN 0.00 3.00 0.05 0.00 0.0 1 0 2D-NOESY 928 V3 3 HN P7 7 HB1 0.00 17.00 0.27 0.00 0.0 5 0 2D-NOESY 514 H 6 HD2 D1 1 HA 0.00 48.00 0.82 0.00 0.0 4 0 2D-NOESY 1152 P7 7 HB2 L10 10 HD21 0.00 180.00 3.30 0.00 0.0 0 2 2D-NOESY 1067 I5 5 HG12 H9 9 HD2 0.00 12.00 0.21 0.00 0.0 0 0 2D-NOESY 811 H9 9 HD2 I5 5 HG11 0.00 12.00 0.21 0.00 0.0 0 0 2D-NOESY 515 H6 6 HE1 D1 1 HA 0.00 20.00 0.36 0.00 0.0 4 0 2D-NOESY 741 L10 10 HN Y4 4 HE1 0.00 26.00 0.44 0.00 0.0 5 1 2D-NOESY 534 H6 6 HN D1 1 HB1 0.00 19.00 0.40 0.00 0.0 5 0 2D-NOESY 820 R2 2 HG1 I5 5 HG12 0.00 60.00 1.30 0.00 0.0 2 1 2D-NOESY 703 H6 6 HB2 V3 3 HN 0.00 2.70 0.06 0.00 0.0 1 0 2D-NOESY 1133 Y4 4 HD1 L10 10 HB1 0.00 9.90 0.20 0.00 0.0 5 5 2D-NOESY 806 F8 8 HA I5 5 HG11 0.00 45.00 1.00 0.00 0.0 5 0 2D-NOESY 802 H6 6 HE1 I5 5 HG11 0.00 120.00 2.70 0.00 0.0 4 0 2D-NOESY 901 L10 10 HN H6 6 HD2 0.00 34.00 0.69 0.00 0.0 4 0 2D-NOESY 559 H6 6 HN D1 1 HB2 0.00 15.00 0.35 0.00 0.0 5 0 2D-NOESY 704 H6 6 HD2 V3 3 HN 0.00 11.00 0.25 0.00 0.0 1 0 2D-NOESY 995 Y4 4 HN F8 8 HD1 0.00 16.00 0.33 0.00 0.0 0 1 2D-NOESY 903 D1 1 HB1 H6 6 HE1 0.00 4.90 0.11 0.00 0.0 4 0 2D-NOESY 646 P7 7 HB2 V3 3 HA 0.00 9.10 0.23 0.00 0.0 5 0 2D-NOESY 837 R2 2 HG1 I5 5 HG21 0.00 76.00 1.90 0.00 0.0 2 5 2D-NOESY 755 R2 2 HG1 I5 5 HA 0.00 55.00 1.40 0.00 0.0 2 1 2D-NOESY 528 I5 5 HA D1 1 HB1 0.00 23.00 0.58 0.00 0.0 5 0 2D-NOESY 676 P7 7 HB2 V3 3 HG21 0.00 31.00 0.79 0.00 0.0 5 2 2D-NOESY 618 I5 5 HA R2 2 HG1 0.00 54.00 1.40 0.00 0.0 2 1 2D-NOESY 794 D1 1 HB1 I5 5 HG11 0.00 32.00 0.85 0.00 0.0 5 0 2D-NOESY 875 R2 2 HA H6 6 HA 0.00 37.00 1.00 0.00 0.0 5 0 2D-NOESY 630 P7 7 HG1 R2 2 HG1 0.00 31.00 0.78 0.00 0.0 2 3 2D-NOESY 740 L10 10 HB1 Y4 4 HE1 0.00 21.00 0.49 0.00 0.0 5 5 2D-NOESY 846 D1 1 HB1 I5 5 HD1 0.00 100.00 3.00 0.00 0.0 5 2 2D-NOESY 840 H6 6 HE1 I5 5 HG21 0.00 330.00 10.00 0.00 0.0 4 2 2D-NOESY 1111 H6 6 HD2 H9 9 HN 0.00 22.00 0.60 0.00 0.0 1 0 2D-NOESY 666 P7 7 HB1 V3 3 HG11 0.00 31.00 0.93 0.00 0.0 5 2 2D-NOESY 1151 P7 7 HB2 L10 10 HD11 0.00 110.00 3.50 0.00 0.0 0 2 2D-NOESY 955 D1 1 HA P7 7 HD1 0.00 6.50 0.21 0.00 0.0 5 0 2D-NOESY 890 L10 10 HD21 H6 6 HA 0.00 21.00 0.64 0.00 0.0 0 2 2D-NOESY 552 I5 5 HA D1 1 HB2 0.00 15.00 0.51 0.00 0.0 5 0 2D-NOESY 817 D1 1 HB2 I5 5 HG12 0.00 23.00 0.71 0.00 0.0 5 0 2D-NOESY 645 P7 7 HB1 V3 3 HA 0.00 9.60 0.34 0.00 0.0 5 0 2D-NOESY 710 P7 7 HD2 V3 3 HN 0.00 1.30 0.04 0.00 0.0 1 0 2D-NOESY 554 I5 5 HG12 D1 1 HB2 0.00 22.00 0.71 0.00 0.0 5 0 2D-NOESY 889 L10 10 HD11 H6 6 HA 0.00 21.00 0.69 0.00 0.0 0 2 2D-NOESY 966 L10 10 HA P7 7 HD1 0.00 13.00 0.46 0.00 0.0 5 0 2D-NOESY 851 H6 6 HE1 I5 5 HD1 0.00 330.00 12.00 0.00 0.0 4 2 2D-NOESY 735 D1 1 HB2 Y4 4 HE1 0.00 46.00 1.20 0.00 0.0 5 1 2D-NOESY 854 H9 9 HE1 I5 5 HD1 0.00 38.00 1.20 0.00 0.0 0 2 2D-NOESY 1065 I5 5 HB H9 9 HD2 0.00 8.00 0.29 0.00 0.0 0 0 2D-NOESY 549 Y4 4 HD1 D1 1 HB2 0.00 72.00 2.00 0.00 0.0 5 1 2D-NOESY 896 D1 1 HA H6 6 HD2 0.00 21.00 0.82 0.00 0.0 4 0 2D-NOESY 701 H6 6 HA V3 3 HN 0.00 2.00 0.08 0.00 0.0 1 0 2D-NOESY 680 F8 8 HD1 V3 3 HG21 0.00 19.00 0.77 0.00 0.0 0 5 2D-NOESY 891 L10 10 HN H6 6 HA 0.00 13.00 0.56 0.00 0.0 5 0 2D-NOESY 555 I5 5 HN D1 1 HB2 0.00 14.00 0.59 0.00 0.0 5 0 2D-NOESY 977 V3 3 HG21 F8 8 HA 0.00 6.70 0.30 0.00 0.0 5 2 2D-NOESY 529 I5 5 HB D1 1 HB1 0.00 15.00 0.66 0.00 0.0 5 0 2D-NOESY 550 Y4 4 HE1 D1 1 HB2 0.00 36.00 1.20 0.00 0.0 5 1 2D-NOESY 893 R2 2 HG1 H6 6 HB1 0.00 24.00 1.00 0.00 0.0 2 1 2D-NOESY 970 V3 3 HA P7 7 HD2 0.00 51.00 2.40 0.00 0.0 5 0 2D-NOESY 848 R2 2 HG1 I5 5 HD1 0.00 120.00 5.80 0.00 0.0 2 5 2D-NOESY 644 P7 7 HB1 R2 2 HD1 0.00 13.00 0.34 0.00 0.0 2 1 2D-NOESY 795 D1 1 HB2 I5 5 HG11 0.00 16.00 0.75 0.00 0.0 5 0 2D-NOESY 1005 Y4 4 HN F8 8 HE1 0.00 29.00 0.73 0.00 0.0 0 1 2D-NOESY 625 H6 6 HE1 R2 2 HG1 0.00 34.00 1.50 0.00 0.0 2 1 2D-NOESY 799 V3 3 HG11 I5 5 HG11 0.00 730.00 37.00 0.00 0.0 5 2 2D-NOESY 1009 I5 5 HN F8 8 HE1 0.00 88.00 4.30 0.00 0.0 0 1 2D-NOESY 758 H9 9 HE1 I5 5 HA 0.00 16.00 0.74 0.00 0.0 0 0 2D-NOESY 548 Y4 4 HA D1 1 HB2 0.00 27.00 1.20 0.00 0.0 5 0 2D-NOESY 892 R2 2 HB1 H6 6 HB1 0.00 19.00 0.90 0.00 0.0 5 1 2D-NOESY 823 H6 6 HE1 I5 5 HG12 0.00 48.00 2.70 0.00 0.0 4 0 2D-NOESY 622 H6 6 HB1 R2 2 HG1 0.00 20.00 1.00 0.00 0.0 2 1 2D-NOESY 724 R2 2 HB1 Y4 4 HA 0.00 180.00 10.00 0.00 0.0 5 1 2D-NOESY 553 I5 5 HB D1 1 HB2 0.00 11.00 0.59 0.00 0.0 5 0 2D-NOESY 929 Y4 4 HN P7 7 HB1 0.00 12.00 0.70 0.00 0.0 5 0 2D-NOESY 1064 I5 5 HA H9 9 HD2 0.00 8.40 0.46 0.00 0.0 0 0 2D-NOESY 836 D1 1 HB2 I5 5 HG21 0.00 15.00 0.88 0.00 0.0 5 2 2D-NOESY 1116 F8 8 HZ H9 9 HN 0.00 30.00 2.00 0.00 0.0 1 0 2D-NOESY 696 Y4 4 HE1 V3 3 HN 0.00 15.00 0.94 0.00 0.0 0 1 2D-NOESY 1141 P7 7 HA L10 10 HB1 0.00 31.00 2.30 0.01 0.0 0 2 2D-NOESY 629 P7 7 HD2 R2 2 HG1 0.00 18.00 1.20 0.01 0.0 2 1 2D-NOESY 843 H9 9 HE1 I5 5 HG21 0.00 26.00 1.40 0.01 0.0 0 2 2D-NOESY 1140 H6 6 HN L10 10 HB1 0.00 3.70 0.26 0.01 0.0 0 2 2D-NOESY 1134 Y4 4 HE1 L10 10 HB1 0.00 7.70 0.49 0.01 0.0 5 5 2D-NOESY 934 H9 9 HB1 P7 7 HB1 0.00 47.00 3.90 0.01 0.0 5 0 2D-NOESY 793 D1 1 HA I5 5 HG11 0.00 29.00 2.30 0.01 0.0 5 0 2D-NOESY 731 P7 7 HB2 Y4 4 HD1 0.00 82.00 6.60 0.01 0.0 5 1 2D-NOESY 682 F8 8 HZ V3 3 HG21 0.00 7.40 0.62 0.01 0.0 0 2 2D-NOESY 885 H9 9 HD2 H6 6 HA 0.00 41.00 2.90 0.01 0.0 0 0 2D-NOESY 723 D1 1 HA Y4 4 HA 0.00 41.00 4.00 0.01 0.0 5 0 2D-NOESY 847 D1 1 HB2 I5 5 HD1 0.00 28.00 2.70 0.01 0.0 5 2 2D-NOESY 733 D1 1 HA Y4 4 HE1 0.00 66.00 5.10 0.01 0.0 5 1 2D-NOESY 675 P7 7 HB1 V3 3 HG21 0.00 12.00 1.20 0.01 0.0 5 2 2D-NOESY 628 P7 7 HD1 R2 2 HG1 0.00 18.00 1.70 0.01 0.0 2 1 2D-NOESY 709 P7 7 HD1 V3 3 HN 0.00 0.50 0.05 0.01 0.0 1 0 2D-NOESY 971 V3 3 HN P7 7 HD2 0.00 9.40 0.95 0.01 0.0 5 0 2D-NOESY 895 R2 2 HG1 H6 6 HB2 0.00 14.00 1.30 0.01 0.0 2 1 2D-NOESY 512 I5 5 HG21 D1 1 HA 0.00 22.00 2.30 0.01 0.0 5 2 2D-NOESY 819 R2 2 HD1 I5 5 HG12 0.00 15.00 1.40 0.01 0.0 2 1 2D-NOESY 1137 H6 6 HA L10 10 HB1 0.00 8.80 0.77 0.01 0.0 0 2 2D-NOESY 888 L10 10 HB1 H6 6 HA 0.00 8.70 0.77 0.01 0.0 5 2 2D-NOESY 1153 P7 7 HD2 L10 10 HD11 0.00 11.00 1.20 0.01 0.0 0 2 2D-NOESY 626 H6 6 HN R2 2 HG1 0.00 11.00 1.30 0.01 0.0 2 1 2D-NOESY 1139 H6 6 HD2 L10 10 HB1 0.00 7.70 0.78 0.01 0.0 0 2 2D-NOESY 967 L10 10 HN P7 7 HD1 0.00 7.10 0.84 0.02 0.0 5 0 2D-NOESY 902 D1 1 HA H6 6 HE1 0.00 3.40 0.36 0.02 0.0 4 0 2D-NOESY 982 I5 5 HG12 F8 8 HA 0.00 8.80 1.10 0.02 0.0 5 0 2D-NOESY 1142 P7 7 HB1 L10 10 HB1 0.00 23.00 2.70 0.02 0.0 0 2 2D-NOESY 935 L10 10 HA P7 7 HB1 0.00 15.00 1.90 0.02 0.0 5 0 2D-NOESY 818 R2 2 HA I5 5 HG12 0.00 29.00 3.70 0.02 0.0 5 0 2D-NOESY 695 Y4 4 HD1 V3 3 HN 0.00 19.00 2.30 0.02 0.0 0 1 2D-NOESY 1143 P7 7 HD1 L10 10 HB1 0.00 12.00 1.10 0.02 0.0 0 2 2D-NOESY 623 H6 6 HB2 R2 2 HG1 0.00 12.00 1.30 0.02 0.0 2 1 2D-NOESY 511 I5 5 HG11 D1 1 HA 0.00 19.00 2.30 0.02 0.0 5 0 2D-NOESY 4 6 N 6 HN 1 O 0.00 10.00 0.73 0.02 0.0 0 16 HBOND 1020 H9 9 HE1 F8 8 HN 0.00 14.00 1.30 0.02 0.0 1 0 2D-NOESY 620 I5 5 HN R2 2 HG1 0.00 34.00 4.30 0.02 0.0 2 1 2D-NOESY 998 I5 5 HG11 F8 8 HD1 0.00 29.00 4.00 0.02 0.0 0 1 2D-NOESY 1138 H6 6 HB2 L10 10 HB1 0.00 9.60 0.98 0.02 0.0 0 2 2D-NOESY 797 R2 2 HD1 I5 5 HG11 0.00 14.00 1.60 0.02 0.0 2 1 2D-NOESY 964 H9 9 HA P7 7 HD1 0.00 27.00 3.90 0.02 0.0 5 0 2D-NOESY 669 D1 1 HB1 V3 3 HG21 0.00 120.00 16.00 0.02 0.0 5 2 2D-NOESY 509 I5 5 HB D1 1 HA 0.00 11.00 1.50 0.02 0.0 5 0 2D-NOESY 1154 P7 7 HD2 L10 10 HD21 0.00 8.60 1.10 0.02 0.0 0 2 2D-NOESY 796 R2 2 HA I5 5 HG11 0.00 29.00 4.30 0.02 0.0 5 0 2D-NOESY 876 R2 2 HB1 H6 6 HA 0.00 16.00 2.00 0.02 0.0 5 1 2D-NOESY 1150 P7 7 HB1 L10 10 HD21 0.00 16.00 2.40 0.03 0.0 0 2 2D-NOESY 979 I5 5 HB F8 8 HA 0.00 8.60 1.40 0.03 0.0 5 0 2D-NOESY 803 P7 7 HB1 I5 5 HG11 0.00 31.00 5.20 0.03 0.0 5 0 2D-NOESY 551 Y4 4 HN D1 1 HB2 0.00 19.00 3.20 0.03 0.0 5 0 2D-NOESY 997 I5 5 HB F8 8 HD1 0.00 28.00 5.00 0.03 0.0 0 1 2D-NOESY 621 H6 6 HA R2 2 HG1 0.00 13.00 2.10 0.03 0.0 2 1 2D-NOESY 697 I5 5 HB V3 3 HN 0.00 2.40 0.40 0.03 0.0 1 0 2D-NOESY 824 P7 7 HB1 I5 5 HG12 0.00 30.00 5.30 0.03 0.0 5 0 2D-NOESY 15 3D 8 N 3D 9 N 130.00 36.00 130.00 0.03 0.0 0 0 TDIHEDRALS 508 Y4 4 HE1 D1 1 HA 0.00 40.00 5.10 0.03 0.1 5 1 2D-NOESY 834 D1 1 HA I5 5 HG21 0.00 13.00 2.30 0.04 0.0 5 2 2D-NOESY 969 R2 2 HG1 P7 7 HD2 0.00 7.10 1.20 0.04 0.0 2 1 2D-NOESY 668 P7 7 HD2 V3 3 HG11 0.00 19.00 3.50 0.04 0.0 5 2 2D-NOESY 756 F8 8 HD1 I5 5 HA 0.00 23.00 4.40 0.04 0.0 0 1 2D-NOESY 11 3J 1 HA 3J 1 HB1 13.00 1.00 13.00 0.04 0.0 0 1 JCOUP 933 H6 6 HE1 P7 7 HB1 0.00 16.00 3.10 0.04 0.0 4 0 2D-NOESY 981 I5 5 HG11 F8 8 HA 0.00 5.30 1.00 0.04 0.0 5 0 2D-NOESY 932 I5 5 HG12 P7 7 HB1 0.00 27.00 5.30 0.04 0.0 5 0 2D-NOESY 487 L10 10 HD11 L10 10 HA 1200.00 460.00 1100.00 0.04 0.1 0 5 2D-NOESY 737 P7 7 HB2 Y4 4 HE1 0.00 120.00 23.00 0.04 0.0 5 1 2D-NOESY 5 3D 5 C 3D 6 C −93.00 46.00 −97.00 0.04 0.1 0 0 TDIHEDRALS 1113 P7 7 HD1 H9 9 HN 0.00 3.10 0.62 0.05 0.1 0 0 2D-NOESY 879 V3 3 HN H6 6 HA 0.00 8.40 1.70 0.05 0.1 5 0 2D-NOESY 226 Y4 4 HB1 V3 3 HG21 270.00 110.00 270.00 0.05 0.1 5 5 2D-NOESY 531 I5 5 HG12 D1 1 HB1 0.00 3.90 0.79 0.05 0.1 5 0 2D-NOESY 1149 P7 7 HB1 L10 10 HD11 0.00 12.00 2.50 0.05 0.1 0 2 2D-NOESY 1144 P7 7 HD2 L10 10 HB1 0.00 9.10 1.50 0.05 0.3 0 2 2D-NOESY 883 F8 8 HD1 H6 6 HA 0.00 41.00 9.40 0.06 0.1 0 1 2D-NOESY 728 D1 1 HA Y4 4 HD1 0.00 33.00 7.60 0.06 0.1 5 1 2D-NOESY 1068 P7 7 HD1 H9 9 HD2 0.00 26.00 4.70 0.06 0.2 0 0 2D-NOESY 999 I5 5 HG12 F8 8 HD1 0.00 18.00 4.20 0.06 0.1 0 1 2D-NOESY 828 F8 8 HD1 I5 5 HG12 0.00 18.00 4.20 0.06 0.1 0 1 2D-NOESY 574 I5 5 HG12 R2 2 HA 0.00 15.00 3.70 0.06 0.1 5 0 2D-NOESY 530 I5 5 HG11 D1 1 HB1 0.00 3.90 0.85 0.06 0.1 5 0 2D-NOESY 1126 P7 7 HB2 L10 10 HA 0.00 10.00 2.40 0.06 0.1 5 0 2D-NOESY 403 F8 8 HB1 P7 7 HB1 110.00 48.00 110.00 0.06 0.1 5 1 2D-NOESY 898 R2 2 HG1 H6 6 HD2 0.00 24.00 5.20 0.06 0.1 2 1 2D-NOESY 938 L10 10 HN P7 7 HB1 0.00 10.00 2.50 0.06 0.1 5 0 2D-NOESY 690 D1 1 HB2 V3 3 HN 0.00 4.00 0.96 0.07 0.1 1 0 2D-NOESY 1127 F8 8 HN L10 10 HA 0.00 17.00 4.40 0.07 0.1 5 0 2D-NOESY 839 V3 3 HN I5 5 HG21 0.00 45.00 12.00 0.07 0.1 5 2 2D-NOESY 729 D1 1 HB2 Y4 4 HD1 0.00 10.00 2.00 0.07 0.7 5 1 2D-NOESY 980 I5 5 HD1 F8 8 HA 0.00 16.00 4.20 0.08 0.1 5 2 2D-NOESY 643 I5 5 HG12 R2 2 HD1 0.00 6.50 1.40 0.08 0.3 2 1 2D-NOESY 681 F8 8 HE1 V3 3 HG21 0.00 6.30 1.50 0.08 0.3 0 5 2D-NOESY 959 V3 3 HN P7 7 HD1 0.00 5.00 1.20 0.08 0.5 5 0 2D-NOESY 525 V3 3 HA D1 1 HB1 0.00 23.00 6.50 0.08 0.2 5 0 2D-NOESY 878 V3 3 HG11 H6 6 HA 0.00 21.00 6.00 0.09 0.1 5 2 2D-NOESY 825 P7 7 HD1 I5 5 HG12 0.00 40.00 12.00 0.09 0.2 5 0 2D-NOESY 983 I5 5 HG21 F8 8 HA 0.00 16.00 4.70 0.09 0.1 5 2 2D-NOESY 1054 P7 7 HB1 H9 9 HB1 0.00 25.00 7.80 0.10 0.2 5 1 2D-NOESY 254 V3 3 HG21 Y4 4 HB1 250.00 100.00 270.00 0.10 0.4 5 5 2D-NOESY 906 V3 3 HN H6 6 HE1 0.00 7.10 1.60 0.10 0.7 4 0 2D-NOESY 138 P7 7 HA F8 8 HE1 130.00 55.00 130.00 0.10 0.6 0 1 2D-NOESY 913 L10 10 HA H6 6 HE1 0.00 3.70 1.00 0.10 0.5 4 0 2D-NOESY 674 H6 6 HE1 V3 3 HG21 0.00 71.00 16.00 0.11 1.0 4 2 2D-NOESY 1007 I5 5 HG11 F8 8 HE1 0.00 25.00 8.10 0.11 0.3 0 1 2D-NOESY 402 F8 8 HA P7 7 HB1 92.00 37.00 82.00 0.11 0.4 5 0 2D-NOESY 884 F8 8 HE1 H6 6 HA 0.00 26.00 7.20 0.12 1.2 0 1 2D-NOESY 689 D1 1 HB1 V3 3 HN 0.00 3.20 1.00 0.12 0.3 1 0 2D-NOESY 838 V3 3 HB I5 5 HG21 0.00 60.00 20.00 0.13 0.3 5 2 2D-NOESY 911 P7 7 HB2 H6 6 HE1 0.00 8.20 2.80 0.13 0.3 4 0 2D-NOESY 290 Y4 4 HB1 I5 5 HG11 38.00 17.00 35.00 0.13 0.5 5 1 2D-NOESY 617 Y4 4 HB1 R2 2 HG1 0.00 33.00 11.00 0.13 0.7 2 3 2D-NOESY 463 P7 7 HB2 F8 8 HA 100.00 41.00 110.00 0.13 0.4 5 0 2D-NOESY 112 P7 7 HB1 F8 8 HN 170.00 66.00 180.00 0.13 0.4 1 0 2D-NOESY 905 R2 2 HG1 H6 6 HE1 0.00 4.70 1.50 0.14 0.8 2 1 2D-NOESY 757 F8 8 HE1 I5 5 HA 0.00 27.00 8.90 0.14 0.7 0 1 2D-NOESY 725 P7 7 HB1 Y4 4 HA 0.00 6.20 2.30 0.15 0.4 5 0 2D-NOESY 1008 I5 5 HG12 F8 8 HE1 0.00 24.00 8.80 0.15 0.4 0 1 2D-NOESY 1021 L10 10 HB1 F8 8 HN 0.00 3.50 1.30 0.15 0.4 0 2 2D-NOESY 491 H9 9 HB1 L10 10 HA 190.00 74.00 190.00 0.15 0.8 5 1 2D-NOESY 485 L10 10 HA H9 9 HB1 190.00 75.00 190.00 0.15 0.7 5 1 2D-NOESY 1114 P7 7 HD2 H9 9 HN 0.00 1.90 0.70 0.16 0.6 1 0 2D-NOESY 904 R2 2 HA H6 6 HE1 0.00 2.40 0.76 0.16 1.4 4 0 2D-NOESY 699 I5 5 HG12 V3 3 HN 0.00 1.30 0.48 0.16 0.6 1 0 2D-NOESY 899 V3 3 HN H6 6 HD2 0.00 16.00 5.80 0.16 0.8 4 0 2D-NOESY 730 P7 7 HB1 Y4 4 HD1 0.00 23.00 9.20 0.17 0.6 5 1 2D-NOESY 243 I5 5 HG21 Y4 4 HA 480.00 190.00 440.00 0.17 0.8 5 5 2D-NOESY 3 3D 3 C 3D 4 C −120.00 60.00 −95.00 0.17 0.5 0 0 TDIHEDRALS 455 I5 5 HN P7 7 HD2 30.00 12.00 28.00 0.17 1.2 5 1 2D-NOESY 37 I5 5 HG21 Y4 4 HD1 340.00 140.00 330.00 0.17 0.9 5 11 2D-NOESY 624 H6 6 HD2 R2 2 HG1 0.00 14.00 5.20 0.17 0.8 2 1 2D-NOESY 1012 P7 7 HD1 F8 8 HE1 0.00 21.00 7.90 0.17 1.0 0 1 2D-NOESY 910 P7 7 HB1 H6 6 HE1 0.00 7.60 3.10 0.18 0.6 4 0 2D-NOESY 1069 P7 7 HD2 H9 9 HD2 0.00 16.00 5.30 0.20 2.4 0 0 2D-NOESY 6 10 N 10 HN 1 O 0.00 20.00 8.10 0.20 1.1 0 15 HBOND 21 3J 3 HA 3J 3 HN 8.00 0.50 8.00 0.21 1.2 0 0 JCOUP 348 I5 5 HG21 H6 6 HA 140.00 55.00 160.00 0.22 2.0 5 5 2D-NOESY 958 R2 2 HG1 P7 7 HD1 0.00 4.10 1.70 0.23 2.2 2 1 2D-NOESY 673 H6 6 HB1 V3 3 HG21 0.00 14.00 6.80 0.23 0.8 5 2 2D-NOESY 154 F8 8 HD1 H9 9 HN 39.00 15.00 33.00 0.24 1.9 1 1 2D-NOESY 49 V3 3 HG21 Y4 4 HE1 110.00 42.00 120.00 0.24 2.4 5 5 2D-NOESY 962 F8 8 HA P7 7 HD1 0.00 27.00 13.00 0.24 0.8 5 0 2D-NOESY 510 I5 5 HD1 D1 1 HA 0.00 22.00 9.90 0.24 1.2 5 2 2D-NOESY 344 H6 6 HD2 H6 6 HA 320.00 130.00 300.00 0.25 1.6 4 0 2D-NOESY 114 P7 7 HG1 F8 8 HN 77.00 31.00 86.00 0.25 3.6 1 1 2D-NOESY 996 I5 5 HA F8 8 HD1 0.00 9.20 4.40 0.25 1.1 0 1 2D-NOESY 390 F8 8 HD1 P7 7 HA 310.00 120.00 340.00 0.25 2.3 0 1 2D-NOESY 3 3J 5 HA 3J 5 HN 8.60 0.40 8.60 0.25 3.6 0 0 J15DEGC 13 3D 6 N 3D 7 N 120.00 16.00 120.00 0.26 2.7 0 0 TDIHEDRALS 3 3J 5 HA 3J 5 HN 8.60 0.40 8.60 0.26 2.9 0 0 J5DEGC 462 P7 7 HB1 F8 8 HA 70.00 28.00 82.00 0.26 1.5 5 0 2D-NOESY 3 3J 5 HA 3J 5 HN 8.50 0.40 8.60 0.26 4.6 0 0 JCOUP 125 P7 7 HA F8 8 HD1 300.00 120.00 340.00 0.26 2.5 0 1 2D-NOESY 366 H6 6 HE1 H6 6 HB2 62.00 31.00 48.00 0.26 1.2 4 0 2D-NOESY 665 D1 1 HB1 V3 3 HG11 0.00 77.00 37.00 0.26 1.8 5 2 2D-NOESY 228 Y4 4 HE1 V3 3 HG21 100.00 42.00 120.00 0.26 2.8 5 5 2D-NOESY 212 Y4 4 HN V3 3 HB 170.00 71.00 200.00 0.27 2.6 5 0 2D-NOESY 8 3D 8 C 3D 9 C −100.00 42.00 −81.00 0.28 1.2 1 0 TDIHEDRALS 526 V3 3 HB D1 1 HB1 0.00 23.00 11.00 0.28 2.2 5 0 2D-NOESY 877 R2 2 HG1 H6 6 HA 0.00 4.20 2.10 0.29 1.6 2 1 2D-NOESY 909 I5 5 HG12 H6 6 HE1 0.00 5.10 2.70 0.29 1.4 4 0 2D-NOESY 738 H9 9 HE1 Y4 4 HE1 0.00 15.00 5.90 0.30 5.6 0 1 2D-NOESY 694 Y4 4 HB1 V3 3 HN 0.00 3.20 1.70 0.30 1.9 0 1 2D-NOESY 1010 H6 6 HA F8 8 HE1 0.00 16.00 7.20 0.31 8.0 0 1 2D-NOESY 109 F8 8 HE1 F8 8 HN 21.00 8.40 21.00 0.32 4.6 1 1 2D-NOESY 332 Y4 4 HA I5 5 HD1 330.00 130.00 300.00 0.32 3.6 3 2 2D-NOESY 30 3J 3 HA 3J 3 HN 8.00 0.40 8.00 0.33 2.9 0 0 JCOUP 908 I5 5 HG11 H6 6 HE1 0.00 4.80 2.70 0.33 1.8 4 0 2D-NOESY 678 P7 7 HD2 V3 3 HG21 0.00 12.00 6.40 0.33 2.2 5 7 2D-NOESY 349 P7 7 HB1 H6 6 HA 63.00 25.00 76.00 0.34 2.5 5 0 2D-NOESY 8 3J 3 HA 3J 3 HN 7.90 0.40 8.00 0.34 3.5 0 0 J5DEGC 405 F8 8 HE1 P7 7 HB1 44.00 18.00 47.00 0.34 13.0 0 1 2D-NOESY 693 Y4 4 HA V3 3 HN 0.00 4.10 2.20 0.34 2.6 1 0 2D-NOESY 407 H9 9 HN P7 7 HB1 41.00 20.00 32.00 0.34 2.7 5 1 2D-NOESY 101 I5 5 HG21 H6 6 HE1 25.00 10.00 22.00 0.34 3.1 4 5 2D-NOESY 1 3J 3 HA 3J 3 HN 8.10 0.40 8.00 0.34 3.2 0 0 J5DEGC 688 D1 1 HA V3 3 HN 0.00 9.80 5.10 0.35 3.6 1 0 2D-NOESY 253 V3 3 HG11 Y4 4 HB1 160.00 63.00 140.00 0.35 6.6 5 5 2D-NOESY 58 P7 7 HD2 Y4 4 HE1 420.00 170.00 350.00 0.36 6.3 5 1 2D-NOESY 972 Y4 4 HN P7 7 HD2 0.00 11.00 6.20 0.37 3.5 5 0 2D-NOESY 211 V3 3 HN V3 3 HB 410.00 170.00 320.00 0.37 3.3 5 0 2D-NOESY 53 H6 6 HN Y4 4 HE1 220.00 87.00 190.00 0.37 4.1 5 1 2D-NOESY 8 3J 3 HA 3J 3 HN 7.90 0.40 8.00 0.38 4.8 0 0 JCOUP 616 Y4 4 HA R2 2 HG1 0.00 19.00 11.00 0.38 5.5 2 1 2D-NOESY 698 I5 5 HG11 V3 3 HN 0.00 0.95 0.55 0.38 3.2 1 0 2D-NOESY 23 3J 5 HA 3J 5 HN 8.30 0.50 8.60 0.38 7.0 0 0 JCOUP 6 3D 6 C 3D 7 C −71.00 16.00 −61.00 0.39 2.1 0 0 TDIHEDRALS 931 I5 5 HB P7 7 HB1 0.00 14.00 8.40 0.41 3.0 5 0 2D-NOESY 1 3J 3 HA 3J 3 HN 8.10 0.40 8.00 0.41 5.1 0 0 J15DEGC 141 L10 10 HA F8 8 HE1 190.00 81.00 210.00 0.42 9.6 0 1 2D-NOESY 322 H6 6 HD2 I5 5 HG21 180.00 71.00 160.00 0.42 6.5 4 2 2D-NOESY 225 Y4 4 HA V3 3 HG21 200.00 79.00 140.00 0.43 3.0 5 2 2D-NOESY 52 I5 5 HG21 Y4 4 HE1 240.00 95.00 200.00 0.43 5.1 5 11 2D-NOESY 670 D1 1 HB2 V3 3 HG21 0.00 22.00 14.00 0.44 3.7 5 2 2D-NOESY 488 F8 8 HD1 L10 10 HA 110.00 45.00 84.00 0.44 4.7 0 1 2D-NOESY 900 P7 7 HB1 H6 6 HD2 0.00 38.00 23.00 0.44 3.9 4 0 2D-NOESY 24 3J 9 HA 3J 9 HB1 19.00 1.50 18.00 0.44 4.9 0 2 J5DEGC 573 D1 1 HB1 R2 2 HA 0.00 43.00 29.00 0.45 3.1 5 0 2D-NOESY 1145 P7 7 HG1 L10 10 HB1 0.00 23.00 9.10 0.45 31.0 0 5 2D-NOESY 180 R2 2 HD1 R2 2 HA 350.00 170.00 360.00 0.46 5.1 4 1 2D-NOESY 1115 P7 7 HG1 H9 9 HN 0.00 6.10 3.70 0.46 7.0 1 1 2D-NOESY 91 P7 7 HD1 H6 6 HD2 170.00 70.00 180.00 0.46 7.3 4 0 2D-NOESY 894 R2 2 HB1 H6 6 HB2 0.00 2.00 1.10 0.46 7.8 5 1 2D-NOESY 9 3J 5 HA 3J 5 HN 8.50 0.30 8.60 0.46 16.0 0 0 J15DEGC 155 F8 8 HE1 H9 9 HN 7.20 2.90 9.10 0.47 3.7 1 1 2D-NOESY 11 3J 3 HA 3J 3 HN 7.80 0.40 8.00 0.48 8.2 0 0 J5DEGC 613 D1 1 HB2 R2 2 HG1 0.00 33.00 22.00 0.48 3.8 2 1 2D-NOESY 334 Y4 4 HD1 I5 5 HD1 180.00 71.00 200.00 0.49 15.0 5 5 2D-NOESY 12 3J 1 HA 3J 1 HB1 4.50 0.50 4.70 0.50 9.3 0 0 JCOUP 57 P7 7 HD1 Y4 4 HE1 460.00 180.00 400.00 0.50 8.3 5 1 2D-NOESY 336 H6 6 HN I5 5 HD1 610.00 240.00 460.00 0.50 7.5 5 2 2D-NOESY 497 H9 9 HA L10 10 HB1 160.00 64.00 200.00 0.50 6.0 0 2 2D-NOESY 237 V3 3 HG11 Y4 4 HA 120.00 51.00 87.00 0.52 5.9 5 2 2D-NOESY 338 H6 6 HB2 I5 5 HD1 150.00 59.00 110.00 0.52 6.6 5 2 2D-NOESY 852 P7 7 HB1 I5 5 HD1 0.00 33.00 22.00 0.52 6.0 5 2 2D-NOESY 7 3D 7 C 3D 8 C −110.00 52.00 −150.00 0.53 4.0 0 0 TDIHEDRALS 930 I5 5 HA P7 7 HB1 0.00 9.20 6.60 0.53 4.2 5 0 2D-NOESY 90 I5 5 HG21 H6 6 HD2 330.00 130.00 370.00 0.54 8.6 4 5 2D-NOESY 2 3 N 3 HN 1 O 0.00 10.00 4.60 0.54 22.0 0 16 HBOND 25 3J 10 HA 3J 10 HN 7.10 0.50 7.30 0.55 7.8 0 0 JCOUP 307 H6 6 HD2 I5 5 HG12 43.00 17.00 47.00 0.55 12.0 4 0 2D-NOESY 259 I5 5 HG21 Y4 4 HB1 300.00 120.00 220.00 0.55 5.5 5 11 2D-NOESY 461 F8 8 HE1 F8 8 HA 210.00 84.00 150.00 0.55 5.0 0 1 2D-NOESY 113 P7 7 HB2 F8 8 HN 150.00 60.00 190.00 0.57 6.5 1 0 2D-NOESY 291 Y4 4 HD1 I5 5 HG11 40.00 16.00 49.00 0.58 16.0 5 1 2D-NOESY 92 P7 7 HD2 H6 6 HD2 290.00 120.00 240.00 0.59 16.0 4 0 2D-NOESY 1 3J 3 HA 3J 3 HN 8.20 0.40 8.00 0.59 11.0 0 0 JCOUP 419 Y4 4 HD1 P7 7 HD1 120.00 49.00 97.00 0.60 7.6 5 1 2D-NOESY 16 3J 1 HA 3J 1 HB1 5.00 0.50 4.70 0.61 12.0 0 0 J5DEGC 8 3J 3 HA 3J 3 HN 7.90 0.30 8.00 0.61 11.0 0 0 J15DEGC 31 3J 5 HA 3J 5 HN 8.30 0.40 8.60 0.62 19.0 0 0 JCOUP 179 R2 2 HG1 R2 2 HA 730.00 290.00 510.00 0.64 8.1 4 1 2D-NOESY 15 3J 1 HA 3J 1 HB2 8.30 0.50 8.20 0.64 21.0 0 0 J5DEGC 50 I5 5 HN Y4 4 HE1 300.00 120.00 210.00 0.64 8.9 5 1 2D-NOESY 196 R2 2 HB1 R2 2 HD1 1200.00 470.00 880.00 0.65 12.0 4 3 2D-NOESY 16 3J 3 HA 3J 3 HB 7.80 0.50 7.60 0.66 18.0 0 0 JCOUP 23 3J 6 HA 3J 6 HB1 4.70 0.50 4.80 0.67 16.0 0 0 J5DEGC 238 V3 3 HG21 Y4 4 HA 210.00 86.00 140.00 0.67 6.9 5 2 2D-NOESY 34 I5 5 HN Y4 4 HD1 1200.00 470.00 810.00 0.67 9.9 5 1 2D-NOESY 316 Y4 4 HD1 I5 5 HG21 190.00 74.00 130.00 0.68 8.8 5 5 2D-NOESY 10 3J 5 HA 3J 5 HN 8.30 0.40 8.60 0.68 20.0 0 0 JCOUP 1112 P7 7 HB1 H9 9 HN 0.00 3.50 2.80 0.68 7.9 1 0 2D-NOESY 18 3J 6 HA 3J 6 HB1 4.90 0.50 4.80 0.69 23.0 0 0 JCOUP 880 Y4 4 HN H6 6 HA 0.00 13.00 11.00 0.69 9.1 3 0 2D-NOESY 317 Y4 4 HE1 I5 5 HG21 120.00 48.00 90.00 0.69 12.0 5 5 2D-NOESY 399 Y4 4 HE1 P7 7 HB1 32.00 13.00 34.00 0.69 17.0 5 1 2D-NOESY 914 L10 10 HB1 H6 6 HE1 0.00 4.80 3.20 0.70 29.0 0 2 2D-NOESY 7 3J 10 HA 3J 10 HN 7.20 0.40 7.30 0.70 11.0 0 0 J5DEGC 172 R2 2 HB1 D1 1 HA 190.00 76.00 140.00 0.70 12.0 5 1 2D-NOESY 10 3J 10 HA 3J 10 HN 7.20 0.40 7.30 0.70 11.0 0 0 J5DEGC 13 3J 10 HA 3J 10 HN 7.20 0.40 7.30 0.71 11.0 0 0 J5DEGC 184 V3 3 HG21 R2 2 HA 140.00 57.00 99.00 0.71 11.0 5 2 2D-NOESY 481 H9 9 HE1 H9 9 HB1 140.00 56.00 100.00 0.72 11.0 0 1 2D-NOESY 126 P7 7 HB2 F8 8 HD1 260.00 100.00 190.00 0.72 11.0 0 1 2D-NOESY 429 H6 6 HD2 P7 7 HD1 160.00 63.00 180.00 0.72 20.0 4 0 2D-NOESY 7 R2 2 HG1 V3 3 HN 11.00 4.70 11.00 0.74 12.0 2 1 2D-NOESY 13 3J 1 HA 3J 1 HB2 8.40 0.50 8.20 0.74 34.0 0 0 JCOUP 7 3J 10 HA 3J 10 HN 7.40 0.40 7.30 0.76 17.0 0 0 J15DEGC 221 V3 3 HN V3 3 HG21 430.00 180.00 290.00 0.77 12.0 5 2 2D-NOESY 373 I5 5 HG21 H6 6 HB2 290.00 120.00 190.00 0.77 10.0 5 5 2D-NOESY 801 H6 6 HB2 I5 5 HG11 0.00 26.00 22.00 0.78 9.4 5 0 2D-NOESY 357 Y4 4 HE1 H6 6 HB1 420.00 170.00 390.00 0.79 15.0 5 1 2D-NOESY 10 3D 3 N 3D 4 N 130.00 36.00 160.00 0.80 11.0 0 0 TDIHEDRALS 340 P7 7 HA I5 5 HD1 150.00 60.00 110.00 0.81 15.0 5 2 2D-NOESY 1006 I5 5 HB F8 8 HE1 0.00 11.00 9.70 0.81 12.0 0 1 2D-NOESY 86 I5 5 HA H6 6 HD2 320.00 130.00 240.00 0.81 18.0 4 0 2D-NOESY 614 V3 3 HA R2 2 HG1 0.00 53.00 47.00 0.82 11.0 2 1 2D-NOESY 335 Y4 4 HE1 I5 5 HD1 160.00 63.00 110.00 0.83 13.0 5 5 2D-NOESY 450 H6 6 HD2 P7 7 HD2 210.00 83.00 240.00 0.84 20.0 4 0 2D-NOESY 2 3J 4 HA 3J 4 HN 8.00 0.40 7.90 0.84 21.0 0 0 JCOUP 223 R2 2 HA V3 3 HG21 150.00 62.00 99.00 0.84 13.0 5 2 2D-NOESY 217 Y4 4 HB1 V3 3 HG11 220.00 88.00 140.00 0.88 20.0 5 5 2D-NOESY 55 H6 6 HB1 Y4 4 HE1 510.00 200.00 390.00 0.88 22.0 5 1 2D-NOESY 22 3J 6 HA 3J 6 HB1 20.00 1.50 21.00 0.89 20.0 0 2 J5DEGC 289 Y4 4 HA I5 5 HG11 120.00 48.00 75.00 0.89 12.0 5 0 2D-NOESY 446 I5 5 HG21 P7 7 HD2 150.00 58.00 93.00 0.90 15.0 5 5 2D-NOESY 421 I5 5 HN P7 7 HD1 46.00 18.00 29.00 0.90 13.0 5 1 2D-NOESY 104 P7 7 HD2 H6 6 HE1 34.00 13.00 23.00 0.90 18.0 4 0 2D-NOESY 81 H6 6 HN H6 6 HD2 550.00 220.00 400.00 0.92 25.0 4 1 2D-NOESY 672 R2 2 HG1 V3 3 HG21 0.00 29.00 27.00 0.92 13.0 2 5 2D-NOESY 17 3J 5 HA 3J 5 HB 7.90 0.50 7.90 0.92 44.0 0 0 JCOUP 5 3J 8 HA 3J 8 HN 6.70 0.40 6.90 0.93 43.0 0 0 JCOUP 2 3J 4 HA 3J 4 HN 7.70 0.40 7.90 0.94 26.0 0 0 J15DEGC 102 H6 6 HN H6 6 HE1 40.00 16.00 25.00 0.95 18.0 4 1 2D-NOESY 292 Y4 4 HE1 I5 5 HG11 17.00 6.80 22.00 0.95 26.0 5 1 2D-NOESY 1117 L10 10 HA H9 9 HN 0.00 6.50 6.00 0.98 19.0 1 0 2D-NOESY 287 I5 5 HA I5 5 HG11 380.00 150.00 230.00 0.99 14.0 5 0 2D-NOESY 1014 L10 10 HN F8 8 HE1 0.00 28.00 26.00 0.99 20.0 0 1 2D-NOESY 2 3D 2 C 3D 3 C −100.00 34.00 −130.00 1.00 16.0 0 0 TDIHEDRALS 367 Y4 4 HE1 H6 6 HB2 580.00 230.00 430.00 1.00 31.0 5 1 2D-NOESY 4 3D 4 C 3D 5 C −100.00 24.00 −120.00 1.00 16.0 0 0 TDIHEDRALS 305 H6 6 HN I5 5 HG12 230.00 91.00 130.00 1.00 16.0 5 0 2D-NOESY 4 V3 3 HG21 V3 3 HN 19.00 7.50 14.00 1.00 26.0 1 2 2D-NOESY 826 P7 7 HD2 I5 5 HG12 0.00 11.00 11.00 1.00 19.0 5 0 2D-NOESY 677 P7 7 HD1 V3 3 HG21 0.00 6.00 5.90 1.00 20.0 5 2 2D-NOESY 9 3D 2 N 3D 3 N 140.00 36.00 100.00 1.00 19.0 0 0 TDIHEDRALS 32 V3 3 HG11 Y4 4 HD1 180.00 70.00 220.00 1.00 24.0 5 5 2D-NOESY 961 Y4 4 HN P7 7 HD1 0.00 6.30 6.10 1.10 25.0 5 0 2D-NOESY 32 3J 5 HG11 3J 5 HB 5.80 1.00 6.70 1.10 33.0 0 0 JCOUP 907 Y4 4 HN H6 6 HE1 0.00 9.40 8.90 1.10 32.0 4 0 2D-NOESY 128 H9 9 HN F8 8 HD1 280.00 110.00 330.00 1.10 55.0 0 1 2D-NOESY 347 I5 5 HB H6 6 HA 47.00 19.00 27.00 1.10 19.0 5 0 2D-NOESY 845 D1 1 HA I5 5 HD1 0.00 10.00 9.90 1.10 24.0 5 2 2D-NOESY 3 V3 3 HG11 V3 3 HN 51.00 29.00 24.00 1.10 22.0 1 2 2D-NOESY 546 R2 2 HB1 D1 1 HB2 0.00 20.00 20.00 1.10 19.0 3 1 2D-NOESY 24 3J 8 HA 3J 8 HN 6.50 0.50 6.90 1.10 48.0 0 0 JCOUP 2 3J 4 HA 3J 4 HN 7.60 0.40 7.90 1.20 41.0 0 0 J5DEGC 153 F8 8 HB1 H9 9 HN 70.00 28.00 41.00 1.20 29.0 1 1 2D-NOESY 276 Y4 4 HE1 I5 5 HA 170.00 67.00 96.00 1.20 25.0 5 1 2D-NOESY 384 I5 5 HG21 P7 7 HA 370.00 150.00 210.00 1.20 26.0 5 5 2D-NOESY 333 Y4 4 HB1 I5 5 HD1 250.00 99.00 140.00 1.20 26.0 5 5 2D-NOESY 281 H6 6 HD2 I5 5 HA 390.00 150.00 240.00 1.20 34.0 5 0 2D-NOESY 356 H6 6 HE1 H6 6 HB1 89.00 36.00 50.00 1.20 24.0 4 0 2D-NOESY 136 H6 6 HN F8 8 HE1 180.00 77.00 100.00 1.20 25.0 0 3 2D-NOESY 23 3J 6 HA 3J 6 HB2 8.10 0.50 8.00 1.20 47.0 0 0 J5DEGC 103 P7 7 HD1 H6 6 HE1 20.00 8.00 24.00 1.20 61.0 4 0 2D-NOESY 960 Y4 4 HA P7 7 HD1 0.00 11.00 12.00 1.20 22.0 5 0 2D-NOESY 5 3J 8 HA 3J 8 HN 6.60 0.40 6.90 1.20 64.0 0 0 J15DEGC 471 P7 7 HB2 F8 8 HB1 250.00 100.00 140.00 1.20 19.0 5 1 2D-NOESY 95 H6 6 HA H6 6 HE1 36.00 14.00 41.00 1.20 89.0 4 0 2D-NOESY 195 R2 2 HA R2 2 HD1 290.00 120.00 360.00 1.30 58.0 4 1 2D-NOESY 30 V3 3 HA Y4 4 HD1 770.00 310.00 430.00 1.30 25.0 5 3 2D-NOESY 420 Y4 4 HE1 P7 7 HD1 320.00 130.00 400.00 1.30 70.0 5 1 2D-NOESY 40 P7 7 HD1 Y4 4 HD1 170.00 69.00 97.00 1.30 30.0 5 1 2D-NOESY 6 3J 9 HA 3J 9 HN 7.20 0.40 7.10 1.30 56.0 0 0 J15DEGC 130 L10 10 HA F8 8 HD1 150.00 61.00 84.00 1.30 26.0 0 1 2D-NOESY 41 P7 7 HD2 Y4 4 HD1 160.00 66.00 110.00 1.30 31.0 5 1 2D-NOESY 304 Y4 4 HE1 I5 5 HG12 39.00 16.00 22.00 1.30 31.0 5 1 2D-NOESY 351 P7 7 HG1 H6 6 HA 270.00 110.00 390.00 1.30 29.0 5 1 2D-NOESY 850 V3 3 HN I5 5 HD1 0.00 44.00 49.00 1.30 31.0 3 2 2D-NOESY 108 F8 8 HD1 F8 8 HN 150.00 62.00 85.00 1.30 31.0 1 1 2D-NOESY 218 Y4 4 HD1 V3 3 HG11 170.00 67.00 220.00 1.30 40.0 5 5 2D-NOESY 460 F8 8 HD1 F8 8 HA 1400.00 560.00 750.00 1.40 29.0 0 1 2D-NOESY 43 Y4 4 HN Y4 4 HE1 260.00 110.00 150.00 1.40 36.0 5 1 2D-NOESY 7 3J 10 HA 3J 10 HN 7.60 0.40 7.30 1.40 72.0 0 0 JCOUP 17 3J 1 HA 3J 1 HB2 8.70 0.50 8.20 1.40 98.0 0 0 J5DEGC 54 H6 6 HA Y4 4 HE1 1300.00 510.00 700.00 1.40 46.0 5 1 2D-NOESY 372 I5 5 HG12 H6 6 HB2 46.00 20.00 23.00 1.40 31.0 5 0 2D-NOESY 350 P7 7 HB2 H6 6 HA 110.00 42.00 55.00 1.40 30.0 5 0 2D-NOESY 12 3D 5 N 3D 6 N 120.00 18.00 140.00 1.40 37.0 0 0 TDIHEDRALS 441 Y4 4 HD1 P7 7 HD2 99.00 39.00 110.00 1.40 180.0 5 1 2D-NOESY 38 H6 6 HN Y4 4 HD1 250.00 100.00 150.00 1.40 45.0 5 1 2D-NOESY 118 H6 6 HN F8 8 HD1 680.00 270.00 370.00 1.40 37.0 0 3 2D-NOESY 841 P7 7 HB1 I5 5 HG21 0.00 22.00 25.00 1.40 31.0 5 2 2D-NOESY 615 V3 3 HB R2 2 HG1 0.00 17.00 20.00 1.40 28.0 2 1 2D-NOESY 56 H6 6 HB2 Y4 4 HE1 710.00 290.00 430.00 1.40 48.0 5 1 2D-NOESY 912 F8 8 HE1 H6 6 HE1 0.00 23.00 19.00 1.50 160.0 0 1 2D-NOESY 5 3J 8 HA 3J 8 HN 6.50 0.40 6.90 1.50 91.0 0 0 J5DEGC 418 Y4 4 HB1 P7 7 HD1 47.00 20.00 22.00 1.50 34.0 5 1 2D-NOESY 294 H6 6 HA I5 5 HG11 11.00 6.90 19.00 1.50 41.0 5 0 2D-NOESY 486 L10 10 HB1 H9 9 HB1 340.00 140.00 500.00 1.50 51.0 5 5 2D-NOESY 1 3D 1 C 3D 2 C −85.00 26.00 −110.00 1.50 93.0 0 0 TDIHEDRALS 318 H6 6 HN I5 5 HG21 730.00 290.00 380.00 1.50 34.0 5 2 2D-NOESY 229 I5 5 HN V3 3 HG21 170.00 67.00 85.00 1.50 35.0 5 2 2D-NOESY 495 F8 8 HD1 L10 10 HB1 32.00 13.00 45.00 1.50 73.0 0 5 2D-NOESY 442 Y4 4 HE1 P7 7 HD2 250.00 100.00 350.00 1.50 72.0 5 1 2D-NOESY 849 V3 3 HB I5 5 HD1 0.00 77.00 92.00 1.60 56.0 3 2 2D-NOESY 470 P7 7 HB1 F8 8 HB1 210.00 86.00 110.00 1.60 37.0 5 1 2D-NOESY 216 Y4 4 HN V3 3 HG11 580.00 230.00 300.00 1.60 38.0 5 2 2D-NOESY 19 3J 6 HA 3J 6 HB2 8.30 0.50 8.00 1.60 92.0 0 0 JCOUP 157 H9 9 HA H9 9 HD2 600.00 240.00 330.00 1.60 69.0 0 0 2D-NOESY 326 I5 5 HN I5 5 HD1 780.00 320.00 390.00 1.60 38.0 5 2 2D-NOESY 339 H6 6 HD2 I5 5 HD1 160.00 62.00 210.00 1.60 78.0 4 2 2D-NOESY 31 V3 3 HB Y4 4 HD1 210.00 84.00 100.00 1.60 40.0 5 1 2D-NOESY 25 3J 10 HA 3J 10 HB1 21.00 1.50 19.00 1.60 43.0 0 2 J5DEGC 401 H6 6 HN P7 7 HB1 540.00 220.00 790.00 1.60 46.0 5 1 2D-NOESY 359 I5 5 HG21 H6 6 HB1 320.00 130.00 160.00 1.60 40.0 5 5 2D-NOESY 425 I5 5 HG21 P7 7 HD1 190.00 78.00 93.00 1.70 46.0 5 5 2D-NOESY 808 F8 8 HE1 I5 5 HG11 0.00 6.50 8.10 1.70 54.0 0 1 2D-NOESY 224 Y4 4 HN V3 3 HG21 840.00 340.00 420.00 1.70 55.0 5 2 2D-NOESY 494 L10 10 HN L10 10 HB1 870.00 350.00 410.00 1.70 44.0 0 2 2D-NOESY 472 H9 9 HN F8 8 HB1 790.00 320.00 410.00 1.70 54.0 5 1 2D-NOESY 288 Y4 4 HN I5 5 HG11 26.00 10.00 13.00 1.70 50.0 5 0 2D-NOESY 321 H6 6 HB2 I5 5 HG21 170.00 69.00 85.00 1.70 44.0 5 2 2D-NOESY 51 I5 5 HA Y4 4 HE1 200.00 79.00 96.00 1.70 45.0 4 1 2D-NOESY 391 F8 8 HE1 P7 7 HA 89.00 36.00 130.00 1.70 71.0 0 1 2D-NOESY 445 I5 5 HG12 P7 7 HD2 26.00 12.00 11.00 1.80 51.0 5 0 2D-NOESY 14 3J 1 HA 3J 1 HB1 5.30 0.50 4.70 1.80 72.0 0 0 J5DEGC 137 I5 5 HG21 F8 8 HE1 170.00 68.00 84.00 1.80 62.0 0 11 2D-NOESY 105 F8 8 HA H6 6 HE1 33.00 13.00 18.00 1.80 78.0 0 1 2D-NOESY 501 F8 8 HE1 L10 10 HD11 140.00 57.00 78.00 1.80 72.0 0 5 2D-NOESY 6 3J 9 HA 3J 9 HN 7.40 0.40 7.10 1.80 130.0 0 0 J5DEGC 378 P7 7 HG1 P7 7 HA 1100.00 450.00 520.00 1.80 48.0 5 1 2D-NOESY 353 P7 7 HD2 H6 6 HA 1600.00 650.00 700.00 1.80 44.0 5 0 2D-NOESY 303 Y4 4 HD1 I5 5 HG12 93.00 37.00 44.00 1.80 48.0 5 1 2D-NOESY 691 R2 2 HD1 V3 3 HN 3.70 2.40 6.70 1.90 75.0 1 1 2D-NOESY 400 H6 6 HA P7 7 HB1 180.00 72.00 76.00 1.90 51.0 5 0 2D-NOESY 323 P7 7 HA I5 5 HG21 240.00 95.00 110.00 1.90 56.0 5 2 2D-NOESY 314 Y4 4 HA I5 5 HG21 330.00 130.00 150.00 1.90 55.0 5 2 2D-NOESY 368 I5 5 HN H6 6 HB2 130.00 76.00 28.00 1.90 53.0 4 1 2D-NOESY 9 3J 4 HA 3J 4 HN 7.50 0.40 7.90 1.90 100.0 0 0 J5DEGC 9 3J 4 HA 3J 4 HN 7.50 0.40 7.90 2.00 110.0 0 0 JCOUP 255 I5 5 HN Y4 4 HB1 1500.00 590.00 650.00 2.00 57.0 5 1 2D-NOESY 671 R2 2 HD1 V3 3 HG21 0.00 19.00 23.00 2.00 170.0 4 5 2D-NOESY 361 P7 7 HG1 H6 6 HB1 160.00 66.00 73.00 2.00 67.0 5 1 2D-NOESY 496 F8 8 HE1 L10 10 HB1 60.00 24.00 86.00 2.00 120.0 0 5 2D-NOESY 191 R2 2 HA R2 2 HG1 340.00 140.00 510.00 2.00 110.0 4 1 2D-NOESY 431 H6 6 HN P7 7 HD1 350.00 140.00 160.00 2.00 56.0 5 1 2D-NOESY 262 P7 7 HD1 Y4 4 HB1 53.00 21.00 22.00 2.00 62.0 5 1 2D-NOESY 175 V3 3 HG11 D1 1 HB1 77.00 31.00 37.00 2.00 70.0 5 2 2D-NOESY 236 V3 3 HB Y4 4 HA 110.00 44.00 45.00 2.00 56.0 5 0 2D-NOESY 143 L10 10 HD11 F8 8 HE1 370.00 150.00 160.00 2.10 72.0 0 11 2D-NOESY 12 3J 4 HA 3J 4 HN 7.40 0.40 7.90 2.10 120.0 0 0 J5DEGC 371 I5 5 HG11 H6 6 HB2 58.00 24.00 22.00 2.10 66.0 5 0 2D-NOESY 209 Y4 4 HE1 V3 3 HA 160.00 65.00 69.00 2.10 64.0 5 1 2D-NOESY 452 H6 6 HN P7 7 HD2 380.00 150.00 160.00 2.10 65.0 5 1 2D-NOESY 208 Y4 4 HD1 V3 3 HA 660.00 260.00 270.00 2.20 74.0 5 1 2D-NOESY 235 V3 3 HA Y4 4 HA 520.00 210.00 210.00 2.20 71.0 5 1 2D-NOESY 275 Y4 4 HD1 I5 5 HA 390.00 160.00 160.00 2.20 73.0 5 1 2D-NOESY 82 H6 6 HA H6 6 HD2 720.00 290.00 300.00 2.20 74.0 4 0 2D-NOESY 306 H6 6 HA I5 5 HG12 47.00 19.00 19.00 2.20 74.0 5 0 2D-NOESY 937 L10 10 HD21 P7 7 HB1 0.00 1.70 2.40 2.20 90.0 0 2 2D-NOESY 320 H6 6 HB1 I5 5 HG21 170.00 70.00 71.00 2.20 77.0 5 2 2D-NOESY 352 P7 7 HD1 H6 6 HA 1700.00 720.00 660.00 2.20 70.0 5 0 2D-NOESY 430 H6 6 HE1 P7 7 HD1 55.00 22.00 24.00 2.20 83.0 4 0 2D-NOESY 315 Y4 4 HB1 I5 5 HG21 200.00 81.00 77.00 2.30 78.0 5 5 2D-NOESY 132 L10 10 HD11 F8 8 HD1 200.00 79.00 80.00 2.30 82.0 0 11 2D-NOESY 286 I5 5 HN I5 5 HG11 330.00 130.00 130.00 2.30 78.0 5 0 2D-NOESY 193 Y4 4 HD1 R2 2 HG1 52.00 21.00 21.00 2.30 93.0 0 3 2D-NOESY 387 H6 6 HD2 P7 7 HA 78.00 31.00 30.00 2.40 89.0 4 0 2D-NOESY 345 Y4 4 HD1 H6 6 HA 120.00 48.00 170.00 2.40 220.0 5 1 2D-NOESY 1011 P7 7 HB1 F8 8 HE1 0.00 31.00 47.00 2.40 97.0 0 1 2D-NOESY 424 I5 5 HG12 P7 7 HD1 30.00 12.00 12.00 2.40 89.0 5 0 2D-NOESY 194 Y4 4 HE1 R2 2 HG1 40.00 16.00 51.00 2.40 200.0 0 3 2D-NOESY 398 Y4 4 HD1 P7 7 HB1 25.00 9.80 9.20 2.50 99.0 5 1 2D-NOESY 383 Y4 4 HE1 P7 7 HA 80.00 32.00 30.00 2.50 93.0 5 1 2D-NOESY 337 H6 6 HA I5 5 HD1 230.00 91.00 83.00 2.50 88.0 5 2 2D-NOESY 443 I5 5 HB P7 7 HD2 70.00 34.00 17.00 2.50 88.0 5 0 2D-NOESY 444 I5 5 HG11 P7 7 HD2 32.00 14.00 11.00 2.50 90.0 5 0 2D-NOESY 213 V3 3 HN V3 3 HG11 1400.00 540.00 500.00 2.50 92.0 5 2 2D-NOESY 252 V3 3 HB Y4 4 HB1 180.00 73.00 67.00 2.50 89.0 5 1 2D-NOESY 20 3J 3 HA 3J 3 HB 8.30 0.50 7.60 2.50 160.0 0 0 J5DEGC 1146 F8 8 HN L10 10 HB1 0.00 3.70 5.70 2.50 98.0 0 2 2D-NOESY 477 L10 10 HB1 H9 9 HA 550.00 220.00 200.00 2.50 88.0 5 2 2D-NOESY 395 P7 7 HD1 P7 7 HB1 470.00 190.00 170.00 2.50 89.0 5 0 2D-NOESY 396 P7 7 HD2 P7 7 HB1 400.00 160.00 140.00 2.50 91.0 5 0 2D-NOESY 736 P7 7 HB1 Y4 4 HE1 0.00 23.00 34.00 2.50 120.0 5 1 2D-NOESY 346 Y4 4 HE1 H6 6 HA 500.00 200.00 700.00 2.60 250.0 5 1 2D-NOESY 505 F8 8 HE1 L10 10 HD21 290.00 120.00 140.00 2.60 130.0 0 8 2D-NOESY 183 V3 3 HG11 R2 2 HA 500.00 200.00 180.00 2.60 100.0 5 2 2D-NOESY 324 P7 7 HD1 I5 5 HG21 140.00 58.00 48.00 2.60 100.0 5 2 2D-NOESY 936 L10 10 HD11 P7 7 HB1 0.00 1.70 2.50 2.60 130.0 0 2 2D-NOESY 308 I5 5 HN I5 5 HG21 880.00 350.00 300.00 2.70 100.0 5 2 2D-NOESY 341 P7 7 HD1 I5 5 HD1 130.00 53.00 45.00 2.70 100.0 5 2 2D-NOESY 853 P7 7 HG1 I5 5 HD1 0.00 28.00 43.00 2.70 160.0 3 5 2D-NOESY 375 P7 7 HG1 H6 6 HB2 170.00 67.00 59.00 2.70 110.0 5 1 2D-NOESY 256 I5 5 HB Y4 4 HB1 170.00 68.00 59.00 2.70 100.0 5 1 2D-NOESY 804 P7 7 HD1 I5 5 HG11 0.00 7.20 12.00 2.70 130.0 5 0 2D-NOESY 805 P7 7 HD2 I5 5 HG11 0.00 6.70 11.00 2.70 120.0 5 0 2D-NOESY 325 P7 7 HD2 I5 5 HG21 130.00 53.00 46.00 2.70 110.0 5 2 2D-NOESY 886 H9 9 HE1 H6 6 HA 0.00 4.10 5.40 2.70 300.0 0 0 2D-NOESY 192 V3 3 HN R2 2 HG1 140.00 59.00 230.00 2.70 220.0 4 1 2D-NOESY 342 P7 7 HD2 I5 5 HD1 140.00 58.00 47.00 2.80 120.0 5 2 2D-NOESY 35 I5 5 HG11 Y4 4 HD1 150.00 59.00 49.00 2.80 110.0 5 1 2D-NOESY 39 H6 6 HA Y4 4 HD1 510.00 210.00 170.00 2.80 120.0 5 1 2D-NOESY 413 P7 7 HA P7 7 HD1 510.00 200.00 170.00 2.80 110.0 5 0 2D-NOESY 215 R2 2 HA V3 3 HG11 550.00 220.00 180.00 2.80 120.0 5 2 2D-NOESY 726 P7 7 HD2 Y4 4 HB1 0.00 15.00 24.00 2.80 180.0 5 1 2D-NOESY 293 H6 6 HN I5 5 HG11 78.00 34.00 130.00 2.90 140.0 5 0 2D-NOESY 456 H9 9 HE1 P7 7 HD2 16.00 6.40 7.30 2.90 160.0 0 0 2D-NOESY 139 P7 7 HB2 F8 8 HE1 160.00 66.00 50.00 2.90 120.0 0 1 2D-NOESY 178 V3 3 HG11 D1 1 HB2 96.00 39.00 32.00 2.90 130.0 5 2 2D-NOESY 33 3J 5 HG12 3J 5 HB 8.00 0.60 7.70 2.90 240.0 0 0 JCOUP 842 P7 7 HG1 I5 5 HG21 0.00 31.00 52.00 3.00 180.0 3 5 2D-NOESY 261 H6 6 HA Y4 4 HB1 130.00 53.00 40.00 3.00 130.0 5 1 2D-NOESY 965 H9 9 HE1 P7 7 HD1 11.00 4.40 5.50 3.00 170.0 0 0 2D-NOESY 436 P7 7 HA P7 7 HD2 420.00 170.00 130.00 3.00 120.0 5 0 2D-NOESY 437 P7 7 HB1 P7 7 HD2 480.00 190.00 140.00 3.00 130.0 5 0 2D-NOESY 134 F8 8 HA F8 8 HE1 620.00 250.00 190.00 3.00 120.0 0 3 2D-NOESY 249 R2 2 HG1 Y4 4 HB1 35.00 14.00 11.00 3.00 140.0 4 3 2D-NOESY 233 Y4 4 HD1 Y4 4 HA 2500.00 980.00 750.00 3.00 130.0 5 1 2D-NOESY 414 P7 7 HB1 P7 7 HD1 590.00 240.00 170.00 3.10 140.0 5 0 2D-NOESY 248 Y4 4 HE1 Y4 4 HB1 1500.00 580.00 420.00 3.10 140.0 4 3 2D-NOESY 47 R2 2 HG1 Y4 4 HE1 170.00 67.00 51.00 3.10 160.0 0 3 2D-NOESY 5 R2 2 HA V3 3 HN 260.00 100.00 80.00 3.10 160.0 1 0 2D-NOESY 6 R2 2 HB1 V3 3 HN 50.00 20.00 16.00 3.10 150.0 1 1 2D-NOESY 36 I5 5 HG12 Y4 4 HD1 150.00 60.00 44.00 3.10 140.0 5 1 2D-NOESY 222 V3 3 HA V3 3 HG21 2300.00 940.00 710.00 3.10 130.0 5 2 2D-NOESY 171 D1 1 HA D1 1 HA 74000.00 30000.00 21000.00 3.10 140.0 5 0 2D-NOESY 115 P7 7 HD1 F8 8 HN 76.00 30.00 23.00 3.10 130.0 1 0 2D-NOESY 25 Y4 4 HN Y4 4 HD1 1700.00 670.00 500.00 3.20 150.0 5 1 2D-NOESY 370 I5 5 HB H6 6 HB2 96.00 40.00 25.00 3.20 150.0 5 0 2D-NOESY 250 V3 3 HN Y4 4 HB1 130.00 51.00 35.00 3.20 150.0 5 1 2D-NOESY 214 V3 3 HA V3 3 HG11 2300.00 920.00 640.00 3.20 150.0 5 2 2D-NOESY 502 H9 9 HA L10 10 HD11 150.00 61.00 240.00 3.30 270.0 0 2 2D-NOESY 423 I5 5 HG11 P7 7 HD1 50.00 21.00 12.00 3.30 150.0 5 0 2D-NOESY 489 F8 8 HE1 L10 10 HA 160.00 66.00 260.00 3.30 380.0 0 2 2D-NOESY 257 I5 5 HG11 Y4 4 HB1 130.00 51.00 35.00 3.30 150.0 5 1 2D-NOESY 319 H6 6 HA I5 5 HG21 280.00 110.00 74.00 3.30 160.0 5 2 2D-NOESY 881 I5 5 HG11 H6 6 HA 0.00 10.00 19.00 3.30 170.0 3 0 2D-NOESY 202 V3 3 HG21 V3 3 HA 2800.00 1100.00 710.00 3.40 170.0 5 2 2D-NOESY 19 3J 2 HA 3J 2 HB2 6.80 0.50 5.90 3.40 180.0 0 0 J5DEGC 181 V3 3 HN R2 2 HA 6200.00 2500.00 1600.00 3.40 170.0 5 0 2D-NOESY 483 F8 8 HE1 H9 9 HB1 150.00 60.00 41.00 3.40 160.0 0 3 2D-NOESY 127 P7 7 HG1 F8 8 HD1 250.00 100.00 67.00 3.40 160.0 0 3 2D-NOESY 464 H9 9 HN F8 8 HA 1000.00 420.00 1400.00 3.40 570.0 5 0 2D-NOESY 241 I5 5 HG11 Y4 4 HA 300.00 120.00 75.00 3.40 160.0 5 0 2D-NOESY 242 I5 5 HG12 Y4 4 HA 270.00 110.00 65.00 3.40 160.0 5 0 2D-NOESY 174 V3 3 HN D1 1 HB1 81.00 32.00 22.00 3.40 160.0 5 0 2D-NOESY 116 P7 7 HD2 F8 8 HN 77.00 31.00 20.00 3.40 170.0 1 0 2D-NOESY 260 H6 6 HN Y4 4 HB1 190.00 77.00 51.00 3.40 170.0 5 1 2D-NOESY 451 H6 6 HE1 P7 7 HD2 88.00 35.00 23.00 3.50 170.0 4 0 2D-NOESY 474 L10 10 HA F8 8 HB1 97.00 39.00 25.00 3.50 170.0 5 1 2D-NOESY 282 P7 7 HD2 I5 5 HA 140.00 57.00 36.00 3.50 180.0 5 0 2D-NOESY 379 P7 7 HD1 P7 7 HA 660.00 260.00 170.00 3.50 170.0 5 0 2D-NOESY 380 P7 7 HD2 P7 7 HA 530.00 210.00 130.00 3.50 180.0 5 0 2D-NOESY 119 F8 8 HA F8 8 HD1 3100.00 1300.00 750.00 3.60 190.0 0 1 2D-NOESY 199 Y4 4 HE1 R2 2 HD1 210.00 86.00 88.00 3.60 210.0 0 3 2D-NOESY 201 V3 3 HG11 V3 3 HA 2700.00 1100.00 640.00 3.60 190.0 5 2 2D-NOESY 432 F8 8 HD1 P7 7 HD1 76.00 31.00 18.00 3.60 190.0 0 1 2D-NOESY 240 I5 5 HB Y4 4 HA 510.00 210.00 120.00 3.60 180.0 5 0 2D-NOESY 186 Y4 4 HD1 R2 2 HA 83.00 33.00 20.00 3.60 190.0 5 1 2D-NOESY 187 Y4 4 HE1 R2 2 HA 81.00 33.00 21.00 3.60 220.0 5 1 2D-NOESY 234 Y4 4 HE1 Y4 4 HA 630.00 250.00 150.00 3.60 190.0 5 1 2D-NOESY 327 I5 5 HA I5 5 HD1 2900.00 1200.00 670.00 3.60 190.0 5 2 2D-NOESY 490 H9 9 HA L10 10 HA 420.00 170.00 96.00 3.70 190.0 5 0 2D-NOESY 160 F8 8 HN H9 9 HD2 110.00 45.00 28.00 3.70 220.0 0 0 2D-NOESY 142 L10 10 HB1 F8 8 HE1 400.00 160.00 86.00 3.70 190.0 0 5 2D-NOESY 392 H9 9 HN P7 7 HA 170.00 68.00 39.00 3.70 200.0 5 1 2D-NOESY 504 F8 8 HD1 L10 10 HD21 140.00 57.00 220.00 3.70 550.0 0 8 2D-NOESY 44 Y4 4 HA Y4 4 HE1 760.00 320.00 150.00 3.70 200.0 5 1 2D-NOESY 131 L10 10 HB1 F8 8 HD1 200.00 81.00 45.00 3.80 200.0 0 5 2D-NOESY 302 Y4 4 HB1 I5 5 HG12 150.00 59.00 30.00 3.80 210.0 5 1 2D-NOESY 15 3J 2 HA 3J 2 HB2 6.90 0.50 5.90 3.80 230.0 0 0 JCOUP 122 I5 5 HG21 F8 8 HD1 170.00 70.00 38.00 3.80 210.0 0 11 2D-NOESY 258 I5 5 HG12 Y4 4 HB1 140.00 58.00 30.00 3.80 210.0 5 1 2D-NOESY 433 F8 8 HE1 P7 7 HD1 34.00 14.00 7.90 3.80 210.0 0 1 2D-NOESY 204 R2 2 HB1 V3 3 HA 220.00 90.00 47.00 3.80 200.0 5 1 2D-NOESY 449 H6 6 HB2 P7 7 HD2 680.00 270.00 140.00 3.90 220.0 5 0 2D-NOESY 4 3J 6 HA 3J 6 HN 6.40 0.80 7.80 3.90 340.0 0 0 J15DEGC 479 H9 9 HN H9 9 HB1 2300.00 920.00 490.00 3.90 220.0 5 1 2D-NOESY 18 3J 2 HA 3J 2 HB1 6.80 0.50 5.90 3.90 250.0 0 0 J5DEGC 428 H6 6 HB2 P7 7 HD1 550.00 220.00 110.00 3.90 220.0 5 0 2D-NOESY 268 I5 5 HG21 I5 5 HA 5900.00 2400.00 1200.00 3.90 220.0 5 5 2D-NOESY 369 I5 5 HA H6 6 HB2 490.00 200.00 100.00 3.90 210.0 5 0 2D-NOESY 427 H6 6 HB1 P7 7 HD1 640.00 260.00 130.00 3.90 210.0 5 0 2D-NOESY 279 H6 6 HB1 I5 5 HA 430.00 170.00 84.00 4.00 230.0 5 0 2D-NOESY 271 V3 3 HG21 I5 5 HA 410.00 160.00 83.00 4.00 220.0 5 5 2D-NOESY 882 I5 5 HG12 H6 6 HA 0.00 9.70 19.00 4.00 260.0 3 0 2D-NOESY 301 Y4 4 HA I5 5 HG12 320.00 130.00 65.00 4.00 220.0 5 0 2D-NOESY 484 L10 10 HN H9 9 HB1 2400.00 980.00 460.00 4.00 230.0 5 1 2D-NOESY 422 I5 5 HB P7 7 HD1 110.00 44.00 20.00 4.00 230.0 5 0 2D-NOESY 198 Y4 4 HD1 R2 2 HD1 130.00 51.00 28.00 4.00 250.0 0 3 2D-NOESY 448 H6 6 HB1 P7 7 HD2 830.00 330.00 170.00 4.00 230.0 5 0 2D-NOESY 239 I5 5 HN Y4 4 HA 6200.00 2500.00 1200.00 4.10 240.0 5 0 2D-NOESY 280 H6 6 HB2 I5 5 HA 570.00 230.00 100.00 4.10 240.0 5 0 2D-NOESY 364 H6 6 HN H6 6 HB2 1400.00 580.00 240.00 4.10 240.0 5 0 2D-NOESY 415 P7 7 HB2 P7 7 HD1 660.00 260.00 130.00 4.10 230.0 5 0 2D-NOESY 459 F8 8 HA F8 8 HA 20000.00 8200.00 3800.00 4.10 240.0 5 0 2D-NOESY 266 I5 5 HG11 I5 5 HA 1200.00 490.00 230.00 4.10 230.0 5 0 2D-NOESY 358 I5 5 HA H6 6 HB1 460.00 180.00 84.00 4.20 240.0 5 0 2D-NOESY 376 P7 7 HD1 H6 6 HB2 720.00 290.00 110.00 4.20 250.0 5 0 2D-NOESY 4 3J 6 HA 3J 6 HN 6.40 0.80 7.80 4.20 390.0 0 0 J5DEGC 274 Y4 4 HB1 I5 5 HA 450.00 180.00 81.00 4.20 250.0 5 1 2D-NOESY 354 H6 6 HN H6 6 HB1 1200.00 480.00 220.00 4.20 240.0 5 0 2D-NOESY 2 V3 3 HB V3 3 HN 83.00 33.00 15.00 4.20 260.0 1 0 2D-NOESY 807 F8 8 HD1 I5 5 HG11 0.00 2.00 4.00 4.20 280.0 0 1 2D-NOESY 300 Y4 4 HN I5 5 HG12 62.00 25.00 11.00 4.20 240.0 5 0 2D-NOESY 386 H6 6 HA P7 7 HA 420.00 170.00 76.00 4.20 250.0 5 0 2D-NOESY 14 3J 2 HA 3J 2 HB1 6.90 0.50 5.90 4.30 310.0 0 0 JCOUP 309 I5 5 HA I5 5 HG21 3200.00 1300.00 520.00 4.30 260.0 5 2 2D-NOESY 298 I5 5 HA I5 5 HG12 1300.00 530.00 220.00 4.30 260.0 5 0 2D-NOESY 26 Y4 4 HA Y4 4 HD1 4300.00 1700.00 750.00 4.30 260.0 5 1 2D-NOESY 389 F8 8 HB1 P7 7 HA 810.00 320.00 140.00 4.30 260.0 5 1 2D-NOESY 454 F8 8 HE1 P7 7 HD2 48.00 19.00 8.30 4.40 290.0 0 1 2D-NOESY 210 I5 5 HN V3 3 HA 300.00 120.00 42.00 4.40 270.0 5 0 2D-NOESY 447 H6 6 HA P7 7 HD2 4400.00 1800.00 700.00 4.40 270.0 5 0 2D-NOESY 267 I5 5 HG12 I5 5 HA 1400.00 560.00 220.00 4.40 270.0 5 0 2D-NOESY 374 P7 7 HB2 H6 6 HB2 83.00 35.00 10.00 4.40 270.0 5 0 2D-NOESY 362 P7 7 HD1 H6 6 HB1 890.00 360.00 130.00 4.40 270.0 5 0 2D-NOESY 251 V3 3 HA Y4 4 HB1 1000.00 420.00 160.00 4.50 280.0 5 1 2D-NOESY 363 P7 7 HD2 H6 6 HB1 1200.00 480.00 170.00 4.50 280.0 5 0 2D-NOESY 273 Y4 4 HA I5 5 HA 730.00 290.00 110.00 4.50 280.0 5 0 2D-NOESY 182 V3 3 HB R2 2 HA 630.00 250.00 98.00 4.50 280.0 5 0 2D-NOESY 377 P7 7 HD2 H6 6 HB2 1000.00 420.00 140.00 4.50 280.0 5 0 2D-NOESY 438 P7 7 HB2 P7 7 HD2 740.00 300.00 110.00 4.50 280.0 5 0 2D-NOESY 1051 P7 7 HB1 H9 9 HA 0.00 7.60 16.00 4.50 300.0 5 0 2D-NOESY 547 R2 2 HG1 D1 1 HB2 0.00 11.00 22.00 4.60 350.0 2 1 2D-NOESY 245 Y4 4 HB1 Y4 4 HB1 39000.00 15000.00 5400.00 4.60 300.0 5 3 2D-NOESY 453 F8 8 HD1 P7 7 HD2 120.00 48.00 17.00 4.60 300.0 0 1 2D-NOESY 206 Y4 4 HA V3 3 HA 660.00 270.00 93.00 4.60 300.0 5 0 2D-NOESY 482 F8 8 HN H9 9 HB1 190.00 79.00 19.00 4.60 300.0 5 1 2D-NOESY 278 H6 6 HA I5 5 HA 560.00 220.00 75.00 4.60 300.0 5 0 2D-NOESY 277 H6 6 HN I5 5 HA 4500.00 1800.00 560.00 4.70 320.0 5 0 2D-NOESY 469 P7 7 HA F8 8 HB1 1000.00 420.00 140.00 4.70 310.0 5 1 2D-NOESY 107 F8 8 HD1 H6 6 HE1 65.00 26.00 9.20 4.70 330.0 0 1 2D-NOESY 406 H9 9 HE1 P7 7 HB1 34.00 13.00 5.00 4.70 340.0 0 0 2D-NOESY 297 I5 5 HN I5 5 HG12 900.00 360.00 120.00 4.70 310.0 5 0 2D-NOESY 140 P7 7 HG1 F8 8 HE1 190.00 76.00 23.00 4.80 320.0 0 3 2D-NOESY 426 H6 6 HA P7 7 HD1 5100.00 2000.00 660.00 4.80 320.0 5 0 2D-NOESY 1013 H9 9 HN F8 8 HE1 0.00 43.00 91.00 4.80 490.0 0 1 2D-NOESY 270 V3 3 HB I5 5 HA 160.00 63.00 18.00 4.80 330.0 5 0 2D-NOESY 176 D1 1 HB2 D1 1 HB2 28000.00 11000.00 3200.00 4.90 340.0 5 0 2D-NOESY 475 L10 10 HB1 F8 8 HB1 220.00 88.00 21.00 4.90 340.0 5 5 2D-NOESY 46 R2 2 HB1 Y4 4 HE1 380.00 150.00 45.00 4.90 340.0 5 3 2D-NOESY 207 Y4 4 HB1 V3 3 HA 1500.00 580.00 160.00 4.90 340.0 5 1 2D-NOESY 394 P7 7 HB1 P7 7 HB1 9800.00 3900.00 1000.00 5.00 350.0 5 0 2D-NOESY 173 D1 1 HB1 D1 1 HB1 29000.00 12000.00 3000.00 5.00 350.0 5 0 2D-NOESY 197 V3 3 HN R2 2 HD1 110.00 46.00 170.00 5.00 1400.0 4 1 2D-NOESY 246 Y4 4 HN Y4 4 HB1 3400.00 1400.00 350.00 5.00 360.0 5 1 2D-NOESY 385 H6 6 HN P7 7 HA 6100.00 2500.00 580.00 5.10 370.0 5 1 2D-NOESY 111 P7 7 HA F8 8 HN 1300.00 520.00 130.00 5.10 360.0 1 0 2D-NOESY 809 F8 8 HZ I5 5 HG11 0.00 2.00 4.20 5.10 700.0 0 0 2D-NOESY 412 P7 7 HD1 P7 7 HD1 8700.00 3500.00 770.00 5.20 380.0 5 0 2D-NOESY 200 V3 3 HA V3 3 HA 38000.00 15000.00 3000.00 5.20 380.0 5 0 2D-NOESY 435 P7 7 HD2 P7 7 HD2 9200.00 3700.00 800.00 5.20 380.0 5 0 2D-NOESY 507 V3 3 HB D1 1 HA 0.00 23.00 51.00 5.20 470.0 5 0 2D-NOESY 473 L10 10 HN F8 8 HB1 330.00 130.00 22.00 5.30 390.0 5 1 2D-NOESY 465 F8 8 HN F8 8 HB1 4000.00 1600.00 290.00 5.40 400.0 5 1 2D-NOESY 397 Y4 4 HB1 P7 7 HB1 40.00 16.00 2.80 5.40 410.0 5 1 2D-NOESY 476 L10 10 HN H9 9 HA 4200.00 1700.00 300.00 5.40 410.0 5 0 2D-NOESY 263 I5 5 HA I5 5 HA 33000.00 13000.00 1800.00 5.50 430.0 5 0 2D-NOESY 612 D1 1 HA R2 2 HG1 0.00 70.00 160.00 5.50 580.0 2 1 2D-NOESY 296 I5 5 HG12 I5 5 HG12 8900.00 3600.00 570.00 5.50 420.0 5 0 2D-NOESY 33 V3 3 HG21 Y4 4 HD1 220.00 88.00 420.00 5.60 540.0 5 5 2D-NOESY 205 Y4 4 HN V3 3 HA 9200.00 3700.00 400.00 5.70 450.0 5 0 2D-NOESY 404 F8 8 HD1 P7 7 HB1 85.00 34.00 160.00 5.80 1100.0 0 1 2D-NOESY 4 3J 6 HA 3J 6 HN 6.00 0.80 7.80 5.90 690.0 0 0 JCOUP 11 3D 4 N 3D 5 N 120.00 14.00 150.00 6.00 550.0 0 0 TDIHEDRALS 524 R2 2 HG1 D1 1 HB1 0.00 8.70 23.00 6.90 770.0 2 1 2D-NOESY 295 H6 6 HD2 I5 5 HG11 24.00 9.40 46.00 7.30 1300.0 4 0 2D-NOESY 14 3D 7 N 3D 8 N 150.00 28.00 220.00 7.40 790.0 0 0 TDIHEDRALS 21 3J 5 HA 3J 5 HB 9.20 0.50 7.90 8.20 1300.0 0 0 J5DEGC 227 Y4 4 HD1 V3 3 HG21 200.00 79.00 420.00 8.50 1200.0 5 5 2D-NOESY 499 L10 10 HN L10 10 HD11 140.00 57.00 310.00 9.00 1500.0 0 2 2D-NOESY 500 F8 8 HD1 L10 10 HD11 98.00 39.00 220.00 13.00 4500.0 0 8 2D-NOESY 164 L10 10 HB1 H9 9 HD2 87.00 35.00 190.00 13.00 4800.0 0 2 2D-NOESY 506 H9 9 HA L10 10 HD21 87.00 38.00 240.00 21.00 9700.0 0 2 2D-NOESY

EXAMPLE 4 Prediction of the Bioactive Conformation

The bioactive conformation for a ligand molecule is its protein-bound conformation and is highly sought-after for its usefulness in Computer-Aided Molecular Design processes (which are used throughout the Pharmaceutical industry in the development of new drugs). In particular, knowledge of the bioactive conformation is very important to lead optimisation and hit identification. Typically, proteins bind to a ligand molecule in a conformation very close to the global free energy minimum conformation in aqueous solution [45]. The mean dynamic 3D structure in aqueous solution that is determined using the methodology according to the present invention is equivalent to this global free energy minimum conformation. Therefore the mean dynamic 3D structure determined for a molecule using this methodology is an excellent predictor for the molecule's bioactive conformation, and the methodology is therefore of considerable usefulness to Computer-Aided Molecular Design processes. Shown in Table 3 below are several examples for different kinds of molecules where the mean dynamic 3D structure determined with this methodology has accurately predicted the bioactive conformation.

TABLE 3 RMSD values (for all heavy atoms) of the bioactive conformation compared to the mean dynamic 3D structure determined with the methodology according to the present invention. PDB code for bioactive RMSD of mean dynamic 3D Molecule conformation structure vs bioactive (Å) Hyaluronan 2JCQ 1.8 Amikacin 2G5Q 1.1 Streptomycin 1NTB 0.9 Lisinopril 1O86 0.7 Enalaprilat 1UZE 0.6

A particular Computer-Aided Molecular Design technique that would clearly benefit from the near identity of the mean dynamic 3D structure in aqueous solution to the bioactive conformation is Ligand-Based Drug Design.

EXAMPLE 5 Improved Rationality in Medicinal Chemistry

Comparison of the dynamic 3D structures of lisinopril and AngiotensinI obtained using the methods of the present invention revealed areas where lisinopril does not optimally mimic the natural ligand's or bioactive conformation's shape and electrostatic properties.

Using this previously unobtainable information allowed the selection of appropriate modifications to the chemical structure of lisinopril to be realised that would remove flexibilities that were perceived to be disadvantageous to binding energies. In the absence of this 3D-dynamic information, the rationale for such modifications would not have been apparent even to an expert in the field.

One of these suggested modifications (inclusion of a bridging group) anticipated structural features of the next-generation ACE-inhibitor benazeprilat (see FIG. 32) which were independently arrived at via the traditional time-consuming processes of interative rounds of screening, SAR analysis and medicinal chemistry. It is clear from this result that dynamic 3D structures produced according to the present invention can be used to greatly aid lead optimisation decisions by medicinal chemists.

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1-62. (canceled)
 63. A computer implemented method for generating data representing an ensemble of three-dimensional structures of a molecule, the molecule comprising first and second atoms linked by at least one bond, said bond having an associated angle, and the angle varying to generate a plurality of three-dimensional structures of said molecule, the method comprising: receiving data representing said molecule, said data comprising data indicating variability of said angle; and generating an ensemble of structures such that the angle has an associated value selected based upon said variability.
 64. A computer implemented method for simulating the variability of the three-dimensional structure of a molecule, the molecule comprising first and second atoms linked by at least one bond, said bond having an associated angle, and the angle varying to generate a plurality of three-dimensional structures of said molecule, the method comprising: receiving data representing said molecule, said data comprising data indicating variability of said angle; simulating the variability of the three-dimensional structure of the molecule based upon said data indicating variability of said angle; and generating an ensemble of structures such that the angle has an associated value selected based upon said simulating.
 65. A method according to claim 63, wherein the data representing the molecule further comprises data indicating a mean angle for said bond and wherein the data indicating variability of said angle comprises data related to said mean angle.
 66. A method according to claim 63, wherein said data indicating the variability of said bond comprises data indicating that the variability of the bond is zero when: the first and second atoms are linked via a double covalent bond, a triple covalent bond or when the first and second atoms are incorporated into an aromatic ring structure; or zero when one of the first and second atoms is a hydrogen atom or a halogen atom; or when the first and second atoms are incorporated into a three or four-membered ring structure.
 67. A method according to claim 63, wherein said data indicating the variability of said bond comprises data indicating that the variability of the bond is non-zero and exhibits a unimodal variability of bond angles when the first and second atoms are linked via a single covalent bond and: a. one of the first and second atoms is linked to a third atom via a double or triple covalent bond; or b. the first and second atoms are oxygen atoms.
 68. A method according to claim 63, wherein said data indicating the variability of said bond comprises data indicating that the variability of the bond is non-zero and exhibits a bimodal variability of bond angles when the first and second atoms are incorporated into a five or six-membered saturated alicyclic ring structure; or a. the first and second atoms are linked via a single covalent bond and one of the first and second atoms is sp³-hybridised and the other of the first and second atoms is sp²-hybridised; or b. the first and second atoms are linked via a single covalent bond and said single covalent bond is conjugated to at least one further double covalent bond in the molecule.
 69. A method according to claim 63, wherein said data indicating variability of said bond comprises data indicating that the variability of the bond is non-zero and exhibits a trimodal variability of bond angles when the first and second atoms are linked via a single covalent bond and: a. both of the first and second atoms are tetravalent and sp³-hybridised; or b. one of the first and second atoms are sp³-hybridised and the other of the first and second atoms is an oxygen atom.
 70. A method according to claim 63, wherein said angle is a dihedral angle defined between said first and second atoms.
 71. A method according to claim 63, wherein the method further comprises predicting at least one experimental parameter from said generated ensemble of three-dimensional structures of said molecule.
 72. A method according to claim 71, wherein the method further comprises a comparison of said at least one predicted experimental parameter to at least one further parameter derived from at least one physical experiment.
 73. A method according to claim 63, wherein the method further comprises: determining an agreement function based on said comparison; generating further data representing a further ensemble of three-dimensional structures of said molecule; predicting at least one further experimental parameter from said further generated ensemble of three-dimensional structures of said molecule; comparing said at least one further predicted experimental parameter to said at least one parameter derived from at least one physical experiment; determining a further agreement function based on said comparison of the at least one further experimental parameter to said at least one parameter derived from at least one physical experiment; and generating data indicating the ensemble having the best agreement function.
 74. A method according to claim 63, wherein the method further comprises predicting at least two experimental parameters from said generated ensemble of three-dimensional structures of said molecule.
 75. A method according to claim 74, wherein the method further comprises a comparison of said at least two predicted experimental parameters to at least two further parameters derived from at least two physical experiments.
 76. A method according to claim 75, wherein said at least two physical experiments provide data indicative of the three-dimensional structures of said molecule sampled over different time periods or over different ranges of movement of said molecule.
 77. A method according to claim 63, wherein said molecule is selected from the group consisting of an organic molecule, a peptide, a carbohydrate, an antibiotic, a nucleic acid, a lipid, a metabolite, drug molecule, a protein, hyaluronan, lisinospril and AngiotensinI.
 78. A method for generating data representing an optimised ensemble of three-dimensional structures of a molecule selected from a plurality of ensembles of three-dimensional structures of said molecule, wherein each ensemble is generated according to a method according to claim
 63. 79. A method for predicting NMR data using an ensemble of three-dimensional structures of a molecule generated using a method according to claim
 63. 80. A method for simulating a conformation of a molecule, such as a ligand molecule when bound to its intended target by generating an ensemble of three-dimensional structures of said molecule using a method according to claim
 63. 81. Use of an ensemble of three-dimensional structures of a molecule, such as a ligand molecule generated according to a method set out in claim 63 to simulate a conformation of said molecule when bound to its intended target.
 82. A method for simulating a bioactive conformation of a molecule selected from the group consisting of a peptide molecule a carbohydrate molecule and a drug molecule by generating an ensemble of three-dimensional structures of said molecule using a method according to claim
 63. 83. Use of an ensemble of three-dimensional structures of a molecule selected from the group consisting of a peptide molecule a carbohydrate molecule and a drug molecule generated according to a method set out in claim 63 to simulate a bioactive conformation of said molecule.
 84. A method for simulating the hydrogen bond occupancy in a molecule by generating an ensemble of three-dimensional structures of said peptide molecule using a method according to claim
 63. 85. Use of an ensemble of three-dimensional structures of a molecule generated according to a method set out in claim 63 to simulate the hydrogen bond occupancy of said molecule.
 86. A data carrier carrying data usable to generate an ensemble of three-dimensional structures of a molecule, the molecule comprising first and second atoms linked by at least one bond, the data comprising data representing said molecule including data indicating variability of said angle.
 87. A carrier medium carrying computer readable instructions configured to cause a computer to carry out a method according to claim
 63. 